Method for Inducing Sustained Immune Response in humans or animal patient suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, cancer, inflammation, and neurodegenerative diseases Inventors: Noreen Griffin, Fengping Shan and Nicholas P. Plotnikoff Assignee: Immune Therapeutics Inc Orlando Florida ABSTRACT A Method for Inducing Sustained Immune Response in humans or animal patient suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, cancer, inflammation, and neurodegenerative diseases comprises daily administration to such patients a single oral tablet, capsule, liquid or cream dose of immediate release Naltrexone in a dose between.01 to 10mg. In order to provide a benefit it the naltrexone must be immediate release and in a dose between .01 and 10mg in order to get the “jumpstart” needed for the brain to send a message out to the adrenal and pituitary glands, alerting them that the body needs more endorphins and to cause a cascade effect on the immune system. Immediate Release Naltrexone between .01 and 10mg was specifically designed to enhance immunomodulation and anticancer properties with fewer side effects then existing therapies. Clinical Studies reveal that immediate release naltrexone between .01 and 10mg not only inhibit angiogenesis but also induce apoptosis and growth arrest in resistant cancer cells. They also prevent the adhesion of cancer cells to bone marrow stromal cells and thereby inhibit the enhanced secretion of migratory factors, such as interleukin (IL)–6, TNF-α , and vascular endothelial growth factor. Where high dose Naltrexone and Slow release Naltrexone between .01mg and 10mg and Immediate Release Naltrexone between .01mg and 10mg share commonality" in categories of genes and are considered the same drug the difference in dosing and delivery method (immediate release) difference in the overall response to the immune system. There is a difference in the cell patterns of genes that are altered by the treatment of immediate release naltrexone verses high does naltrexone and slow release low naltrexone between .01mg and 10mg. The differences are important because immediate release naltrexone between .01 and 10mg has as immunomodulator. Since immediate release naltrexone blocks the opiate receptors only for a few hours before it is naturally excreted, what results is a rebound effect; in
which both the production and utilization of met (5) enkelphine or opiate growth factor are increased. Once the immediate release naltrexone has been metabolized, the elevated endorphins produced as a result of the rebound effect can now interact with the more-sensitive and more-plentiful receptors and assist in regulating cell growth and immunity. There is not rebound effect with either high dose naltrexone or slow release naltrexone and it is the rebound immunomodulatory effect that effects the treatment of treating patients suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, opportunistic infections, cancer, inflammation, and neurodegenerative diseases “Younger J, Clin Rheumatol. 2014; 33(4): 451–459. PMCID: PMC3962576’) Background information on the product
Naltrexone is short for Naltrexone Hydrochloride (C20H23NO4·HCl). Naltrexone is an orally effective opioid receptor antagonist, used as a treatment for opiate addiction. Naltrexone was originally synthesized in 1963 and patented in 1967. In 1984, the US Food and Drug Administration (FDA) approved naltrexone in a 50 mg dose as a treatment for heroin addiction. Naltrexone 50 mg film-coated tablets have been approved in Europe since at least 1989 for the treatment of opiate addiction and more recently alcohol dependency. Product Name: Naltrexone Hydrochloride Chemical Name: 17-(cyclopropylmethyl)-4,5α-epoxy- 3,14-dihydroxymorphinan-6-one Structure:
Naltrexone Naltrexone has been approved in 1980s for use in the treatment of alcoholism or narcotic addiction. It is believed that naltrexone functions by blocking the brain receptors that trigger the effects of alcohol or narcotics. It is usually available in the market as tablets of 50 mg suitable for once daily administration. A new formulation of extendedrelease suspension for intramuscular injection has been approved by FDA in 2006. Naloxone is the first synthesized pure opioid antagonist with the chemical name of ()17 allyl4,5aepoxy3,14dihydroxymorphinan6one and the molecular formula of C19H21N04. The chemical structure of naloxone is shown below.
Naloxone Naloxone is typically administered intravenously because of its short duration of action and low oral bioavailability, and is generally administered to a patient in order to reverse opioid depression, including respiratory depression, induced by natural and synthetic opioids. Nalmefene has the chemical name of 17cyclopropylmethyl4,5aepoxy6 methylenemorphinan3,14diol and the molecular formula of C21H25N03. The chemical structure of nalmefene is shown below.
Nalmefene Nalmefene is typically used in the management of alcohol dependence, and also has been investigated for the treatment of other addictions such as pathological gambling and addiction to shopping. Nalmefene is an opiate derivative similar in both structure and activity to the opiate antagonist naltrexone. Advantages of nalmefene relative to naltrexone include longer halflife, greater oral bioavailability and no observed dose dependent liver toxicity. Like other drugs of this type, nalmefene can precipitate acute withdrawal symptoms in patients who are dependent on opioid drugs, or more rarely when used postoperatively to counteract the effects of strong opioids used in surgery. However in the early 1980s, professor Ian Zagon discovered that low dose naltrexone (LDN) increases the production of endogenous endomorphins and increases the density of opiate receptors. Especially low dose naltrexone increases production of the endogenous pentapeptide metenkephalin, also named by Zagon opioid growth factor (OGF), as well as the number and density of OGF receptors by intermittently blocking the opiate receptors. This intermittent increase enhances homostatic regulation of the natural immune function of the human body. Zagon' s publications inspired Bernard Bihari and his team who began studying low dose naltrexone in patients with AIDS and described the results in the US patent 4888386. They applied these principles to study the use of low dose naltrexone in patients affected by different types of immunemediated conditions like multiple sclerosis, lymphoma, cancer, etc.
In particular, they studied the oral administration of low dose naltrexone in patients suffering from chronic herpes infection, especially genital herpes and described the results in the US patent 5356900. Nicholas Plotnikoff studied the antiviral properties of the OGF whose production is increased by administration of LDN and reported that LDN can be an effective therapy against herpes, HIV infection, cytomegalovirus, coronavirus, influenza A and Japanese encephalitis. BACKGROUND OF THE INVENTION The immune system protects the body against infectious agents, including bacteria, viruses, fungi, and parasites. In addition, the immune system protects against cancer, as well as disease states that result from immune imbalance, opportunistic infections, Stimulation of the immune system by pharmaceuticals is an important approach to the prevention and treatment of agents that cause immune suppressed states. The response by the immune system to an immunogen may be depressed as a consequence of certain diseases or pathological conditions. For example, patients infected with the human immunodeficiency virus (HIV-1) may develop acquired immune deficiency syndrome (AIDS) or AIDS related complex (ARC), and thus have depressed immune responses.
In addition to patients with HIV/AIDS patients
undergoing cancer therapy, suffering from opportunistic infection or inflammatory diseases have a depressed immune system either due to the diseases or the immunosuppressing drug used in the treatment cancer, autoimmune disease and HIV/AIDS. These patients’ classes are more susceptible to pathological infections or malignancies against which a normal immune system would have otherwise provided sufficient protection. Other such immunocompromised individuals include patients with opportunistic infection autoimmune diseases, cancer, or undergoing x-ray, surgery, or chemotherapy treatment. Current treatments used to prevent the development of immunodeficiency in individuals with viral infections, HIV for example, usually involve administration of compounds that inhibit viral DNA synthesis thereby slowing onset of viral-related immunosuppression. More recent treatments against HIV include administration of protease inhibitors such as, for example, saquinovir, nefinavir, ritonavir, indinavir, and others. Cytokine therapy is also used in the treatment of AIDS patients, with research groups having demonstrated efficacy of interleukin-2 (IL2) in elevating the CD4 T-cell subset in HIV positive patients (Kovacs, et al., N. Engl. J. Med., 1996; 335: 1350-1356). Reports have detailed that IL2 can also increase CD8 T-cell count (Schmitz, et al., Science, 1999; 283: 857-860). Unfortunately, the use of IL2 is normally accompanied by major toxicity
(Davey, et al., JAMA, 2000; 284: 183-189). Many of these same drugs are used to treat cancer, autoimmune disease and neurodegenerative diseases. Nevertheless, given the potential promise of these therapies directed toward antiretroviral effects, none have proven to be totally effective in treating or preventing development of AIDS. In addition, many of these compounds cause adverse side effects including black box warning risk of Hematological, toxicity, myopathy, lactic acidosis Hepatic decompensating, lactic acidosis, severe hepatomegaly with steatosis and exacerbation of Hepatitis B, Drug interaction leading to serious and life threating reactions, including sedative hypnotics, etc; hepatic metabolism, skin reactions low platelet count, diarrhea, nausea, renal toxicity, and bone marrow cytopenia (Numerous clinical studies with low dose naltrexone in normal volunteers, HIV positive, Multiple Sclerosis, Autism, Fibromyalgia, Diabetes, and cancer patients showed no major toxicity Current treatments used to prevent the development of immunodeficiency in individuals with autoimmune disease, Crohn’s Disease, Multiple Sclerosis and cancer, for example, usually involve administration of compounds that slow or suppress the immune system response in an attempt to stop the inflammation involved in the autoimmune attack are called immunosuppressive medications. These drugs include corticosteroids (prednisone), methotrexate, cyclophosphamide, azathioprine, and cyclosporin. Unfortunately, these medications also suppress the ability of the immune system to fight infection and have other potentially serious side effects More recent treatments against autoimmune diseases and cancer include administration
of
Glucocorticoids,
Cytostatics
are
nitrogen
(cyclophosphamide), nitrosoureas, platinum compounds; Interferons,
mustards TNF binding
proteins Nevertheless, given the potential promise of these therapies directed toward autoimmune disease and cancer, none have proven to be totally effective in treating or preventing development of autoimmune disease or cancer. In addition, many of these compounds cause adverse side effects including black box warning risk of Hematological, toxicity, myopathy, lactic acidosis Hepatic decompensating, lactic acidosis, severe hepatomegaly with steatosis and exacerbation of Hepatitis B, Drug interaction leading to serious and life threating reactions, including sedative hypnotics, etc; hepatic metabolism, skin reactions low platelet count, diarrhea, nausea, renal toxicity, and bone marrow cytopenia (Numerous clinical studies with immediate release naltrexone
dosed between .01mg and 10mg in normal volunteers, HIV positive,
Multiple Sclerosis, Autism, Fibromyalgia, Diabetes, and cancer patients showed no major toxicity
Thus, there exists a need in the art for improved methods of stimulating a sustained immune system response in patients in need of such treatment, such as patients include those with compromised immune system responses (e.g. the potential to develop compromised immune system responses HIV-infected (e.g. patients AIDS), opportunistic infections, autoimmune disease, cancer, cardio vascular disease, inflammatory diseases, and neurodegenerative diseases. Based on the above, however, there would be no expectation by one of skill in the art that the active agents of the present invention could be used in methods of treatment useful in producing a sustained immune response in a patient comprising administering the active agents on dosage schedule to a patient in need of such treatment. The present invention is based on the surprising discovery that immediate release naltrexone on a regular dosing schedule between .01 and 10mg is effective in promoting a sustained cell increase in immune system response including sustained cell levels. The present invention provides, inter alia, for methods of treatment useful for inducing a sustained immune system response in an immunocompromised patient in need of such treatment wherein the method comprises administering to the patient an effective amount of immediate release naltrexone between .01mg and 10mg, either alone, combined, or in further combination with other compounds useful for increasing immune system response, including vaccines. In this context, “immunocompromised” refers to any reduction in T-cell number or function. The present invention also provides, inter alia, for methods of treatment useful for inducing a sustained immune system response in an HIV-infected patient, wherein the method comprises administering to the HIV-infected patient an effective amount of a immediate release naltrexone between .01 and 10mg, either alone, combined, or in further combination with other compounds useful for slowing the progression of HIV proliferation or HIV-associated infections, including reverse transcriptase inhibitors such as 3′-azido-3′-deoxythymidine (AZT), 2′,3′-dideoxycytidine (DDC) and 2′,3′dideoxyinosine (DDI), zidovudine, didanosine, zalcitabine, stavudine, and viramune; protease inhibitors such as saquinovir, nefinavir, ritonavir, and indinavir; cytokines such as G-CSF, IL-11, IL-12, IL-2; and gamma interferon and antibiotics or other drugs used for the treatment or prevention of infections in HIV-infected patients. Comprises daily administration to such patients a single oral, liquid or cream dose of immediate release naltrexone with a dose between .01mg to 10mg. We know that for Naltrexone to block the opiate receptor but the effect on the immune system only occurs when the opiate receptor is blocked for a short period of time which requires the naltrexone be
immediate release and in a dose of between .01mg and 10mg to have an immunomodulatory effect. Immediate release naltrexone dosed between .01mg and 10mg was specifically designed to enhance immunomodulation and anticancer properties but with less side effects. (“Mohammad A. Seifrabiei, Mohammad Abbasi, Ali Montazeri, Fatemeh Shahnazari and Arash Pooya American Journal of Applied Sciences 5 (7): 872-875, 2008Ref “)
Clinical Studies reveal that immediate release naltrexone between .01 and 10mg not only inhibit angiogenesis but also induce apoptosis and growth arrest in resistant cancer cells. They also prevent the adhesion of cancer cells to bone marrow stromal cells and thereby inhibit the enhanced secretion of migratory factors, such as interleukin (IL)–6, TNF-α , and vascular endothelial growth factor. In research experiment, ovarian cancer cells were treated with either water as the control or different dosing regimens of naltrexone to replicate high dose versus immediate release dosing of naltrexone. Using the immediate release low or short-term dosing of naltrexone, growth of cancer cells were slowed; however, when a high dose of naltrexone was used, cancer cells were stimulated and grew faster. Autoimmune disease, cancer, cardio vascular disease, inflammatory bowel disease, Musculo-skeletal disorders, metabolic disorders and neuro degenerative diseases develop when the immune system begins to dysfunction which can be caused by a number of factors, when organism mount an anti-self response, usually as a result of abnormalities of the afferent parts of the immune system which are involved in antigen-specific responses and Chronic inflammation which can be can be triggered by cellular stress and dysfunction, such as that caused by excessive calorie consumption, environmental factors, elevated blood sugar levels, and oxidative stress. It is now clear that the destructive capacity of chronic inflammation is unprecedented among physiologic processes (Karin et al. 2006). In chronic inflammation you have: causative agent, non-degradable pathogens that cause persistent inflammation, infection with some types of viruses, persistent foreign bodies, overactive immune system reactions and it causes major cells involvement - Macrophages, lymphocytes, plasma cells (these three are mononuclear cells), and fibroblast with Primary mediators - reactive oxygen species, hydrolytic enzymes, IFN-γ and other cytokines, growth factor and long term inflammation causes the destruction of tissue, thickening and scarring of connective tissue (fibrosis), death of cells or tissues (necrosis). Naltrexone when used in immediate releasing dosing between .01mg to 10mg is an immune-modulating drug and as such has more then one mechanism of action in the treatment of immune deficiency diseases, opportunistic infections, autoimmune disease, cancer, cardio vascular disease, chronic infections, inflammatory diseases, inflammatory bowel disease, Musculo-skeletal disorders, metabolic disorders and neurodegenerative
diseases. As an immune-modulating drug it has a cascade benefit effect on the immune system. As an immunomodulatory drug immediate release naltrexone between .01mg and 10mg works by binding for a short period of time with mu receptors. Immediate release naltrexone between .01mg and 10mg has an affinity to at least a million extremely specific delta receptors with immediate release naltrexone between .01mg and 10mg only having a weak binding to only one hundred. Immediate release naltrexone between .01mg and 10mg blocks the mu and upregulate delta receptors so the endorphins released at night binds to the delta not the mu receptors, which results in stimulation of the immune system via delta receptors, the blocking of the mu agonists for longer then 4 to 6 hours suppress the immune system. The block of the mu receptor for a short period causes an increase the products of cytokines including met-enkelphine. This interaction regulates normal cell growth. If too much met-enkelphine or opiate growth fact (“OGF”) OGF is released it slows cell growth and if too little OGF or enkephalin is released the cells proliferate out of control and have the potential to become cancer cells or overactive immune cells. If the naltrexone dose is too high, or not an immediate release dose for example higher than 10mg, then naltrexone is still bound to the opioid receptor and the met-enkephalin cannot interact with the receptor. The end result and risk of taking too high of a dose is that either there will be no effect or the cancer cell can grow
Where high dose Naltrexone, slow release Low Dose Naltrexone and Immediate Release Naltrexone between .01 and 10mg share commonality" in categories of genes and are considered same drug accept the difference between both the type of delivery and the dose determine if naltrexone acts as a immunomodulator and is a benefit to immune comprised patients. . Immediate release naltrexone between .01mg and 10mg blocks opiate receptors temporarily (typically 2-4 hours), which leads to rebound increase in endogenous opioids and endorphins but especially in the production of cytokines which are critical to immune health. (“Critical regulators of cytokine signaling and immune responses International Congress Series Volume 1285, November 2005, Pages 121–129”)
Immediate Release naltrexone between .01mg and 10mg: increases endorphins, inhibits cell proliferation in vivo high dose naltrexone or slow release naltrexone: decreases endorphins, promotes cell growth; Increased endorphin levels, decreased inflammatory cytokines, shift from Th1 (pro-inflammatory) to Th2 (anti-inflammatory), reduces production of TNF and begins to effect TRL4 and TRL9 within 72 hours and reduce inflammation. (“Faith; Robert E.; Faith, Robert E.; Murgo, Anthony J.; Good, Robert A.; Plotnikoff, Nicholas P.Cytokines: Stress and Immunity, Second Edition (Page 362).”).
Parallel with OGFR function, as OGF exhibits cancer growth features similar to immediate release naltrexone in a dose between .01mg and 10mg. But continuous 48h exposure to Naltrexone has no dramatic effect in a number of tumors. No effect on pancreatic cancer cells: MIA-PaCa2, PANC1, and BxPC3. No effect on glioma cells: T98G and U87MG. No effect on A549 (lung) and HCT116 (CRC) no effect Expression of CDK Inhibitors p15, p18, p19, and p27 are not altered by immediate release naltrexone
Continuous exposure naltrexone in a dose between .01mg and 10mg stimulates the growth of tumors. Treatment with immediate release naltrexone in a dose between .01mg and 10mg inhibit tumor growth, this is associated with the short-term blockade of opioid receptors. Blockade causes a compensatory increase in receptors; however, the result of this differs with dose. Immediate release naltrexone in a dose between .01mg and 10mg use associated with cell cycle responses via OGF action on p16 INK4a and p21WAF1/CIPp16. We know that continuous exposure to immediate release naltrexone in a dose between . 01mg and 10mg has a dramatic effect in the number of tumors such as pancreatic cancer cells, glioma cells, TRL9, TRL4, and T-cell productions and beta-endorphin levels. The effect on beta-endorphin levels is very important because beta-endorphin levels are reduced to 1/8 to Ÿ normal levels in autoimmune related and rheumatic disease as Fibromyalgia, MS, Crohn’s Disease, endometriosis, cluster headaches, chronic migraines, lupus, arthritis and gout. Immediate release naltrexone in a dose between .01mg and 10mg has been shown to increase beta-endorphines levels, which shift the balance from Th1 to Th2 cells to decrease inflammation. Like opiate receptors Toll like receptors are present throughout the body. They are part of your bodies first line defense mechanism against invading pathogens. (Such as viruses, parasites, bacteria, protozoae etc.) Basically, these receptors spot "non-human" proteins and start a defense against them. We found that not all the cytokine expressions by the macrophage were decreased while TLR9 was downregulated, IL-12, TNF-alpha, IFN-gamma and IL-1beta expressions were significantly decreased, but IL-6, IFN-beta and IL-10 expressions were not affected. Interestingly, the level of IFN-alpha was even increased. This alteration of cytokines produced by TLR9-downregulated APCs upon CpG ODN stimulation might indicate that the role of CpG DNA is more complicated in the pathogenesis and prevention of diseases. In addition LR2 and TLR9 and costimulation of TLRs have been
shown to induce HIV replication. Together these results underscore the importance of TLRs in bacterial Ag- and CpG DNA-induced HIV-LTR trans-activation and HIV replication. These observations may be important in understanding the role of the innate immune system and the molecular mechanisms involved in the increased HIV replication and HIV disease progression associated with multiple opportunistic infections. Based on the present evidence, it is likely that TRL9-activated immune responses to the CpG motif in GEM91 were responsible for the observed increases in viral load, and that CpG motif in oligonucleotide phosphorothioates is biologically active. (“J Immunol. 2003 May 15;170(10):5159-64.)”Toll-like receptor 2 (TLR2) and TLR9 signaling results in HIV-long terminal repeat trans-activation and HIV replication in HIV-1 transgenic mouse spleen cells: implications of simultaneous activation of TLRs on HIV replication.) Which once again provides evidence of the value of LDN in the treatment of HIV/AIDS which no prior art has provided the connection between immediate release naltrexone in a dose between .01mg and 10mg as effective the regulations of TRL9 in the stopping of the progression of HIV/AIDS and opportunistic infections. (“Plotnikoff NP, Wybran J: Methionine-enkephalin shows promise in reducing HIV in blood. Ann N Y Acad Sci. 1987;496:108-14. PMID: 3496822”) It is thought that many autoimmune diseases are caused by feedback loops. For example, chronic infection can cause huge inflammatory response (such as Epstein Barr, Crohn’s Disease, IBS, Fibromyalgia) and the excess inflammatory response damages cells in the body in the effort to kill the infection. During this process, the TLR-4 receptors are constantly being stimulated to fight off an infection, which does not exist, because the TLR-4 receptors are being stimulated all the time by natural parts of your blood. This, unfortunately, leads to the body ignoring real infections and the body beings to attack healthy cells. Resulting in the broad spectrum of autoimmune diseases. Immediate release naltrexone in a dose between .01mg and 10mg reduces nitric oxide synthase activity, inhibits glutamate formation and microglial activity, and reduces proinflammatory cytokine and neurotoxic superoxide production. Filamin A modulates the mu opioid receptor. Immediate release naltrexone in a dose between .01mg and 10mg effect Adenosine receptors is involved in pain signaling and intrathecal adenosine suppresses pain. It is via the non-opioid antagonist path that immediate release naltrexone at a dose between .01 and 10mg exerts its anti-inflammatory effects. Microglia are central nervous system immune cells that are activated by a wide range of triggers. Once activated, microglia produce inflammatory and excitatory factors that can cause sickness behaviors
such as pain sensitivity, fatigue, cognitive disruption, sleep disorders, mood disorders, and general malaise. When chronically activated, the resulting proinflammatory cascade may become neurotoxic, causing several deleterious effects. Given the wide variety of diseases that are caused by increase inflammatory factors produced by activated microglia (e.g., proinflammatory cytokines, substance P, nitric oxide, and excitatory amino acids) a range of symptoms and medical outcomes could share the pathophysiological mechanism of central inflammation. Conditions such as fibromyalgia may involve chronic glial cell activation and subsequent production of pro-inflammatory factors. The hypothesis is indirectly and partially supported by the high degree of symptomatic overlap between fibromyalgia and cytokine-induced sickness behaviors. Immediate release naltrexone at a dose between .01 and 10mg blocks the TLR-4 receptor experimentally, and in vivo. (In a test tube and also humans) Blocking these receptors causes the whole cycle to activate or re-balance and the immune system gradually return too normal. (“Faith, RE, Murgo, AJ, Good RA, Plotnikoff NP. (2012)”). Cytokines: Stress and Immunity, Second Edition Unfortunately, the TLR-4 receptors probably cannot "unlearn" to react to something, so the treatment with LDN is long term and will control the symptoms after varying periods of initial treatment, depending on which set of TLR-4 receptors are malfunctioning. Crohn’s patients have positive response due to the number of TLR-4 and TRL-9 receptors in the bowel and intestines. Studies have shown when patients stopped Immediate release naltrexone at a dose between .01 and 10mg in have seen the return of the chronic disease and symptoms and when patients start Immediate release naltrexone at a dose between . 01 and 10mg protocol the symptoms subside once again. The Central Nervous system (CNS) is made up of nerves and cells called glia, the function of the glia is to provide immune protection and provide defense to the CNS. Under normal conditions the glia remain in an inactivate state. They become activated readily in response to infection or injury. The most important change that happens during inflammation of the brain and spinal cord (Central Nervous System) is activation of glia cells, which is why Immediate release naltrexone at a dose between .01 and 10mg helps with neuro degenerative diseases. When glia cells are activated they trigger the release of certain chemicals known as proinflammatory and neurotoxic factors. These factors include several cytokines such as tumor necrosis factor alpha (TNF-α) and interleukin one beta (IL1-β), fatty acid metabolites and free radicals such as nitric oxide and superoxide. In painful conditions such as Complex regional pain and fibromyalgia and neuropathic pain, damage to the peripheral nerves shifts the glia to an activated state within the spinal cord.
The glia cells are made up of microglia and astrocytes The microglia guard and protect the immune system and the astrocytes help maintain cell fluid balance which is important for the action of chemicals in the cells called neurotransmitters (needed to control nerve function). Glia cells are activated by trauma, surgery, injury, infection, and opioids. When activated, glia release pro-inflammatory and neurotoxic factors (cytokines). Opiate antagonist that block the effect of opioids has been shown to help prevent activation of glia. LDN has been shown to inhibit the activation of glia. (“Younger, J et al. Arthritis Rheum. 2013; 65 (2): 529-538’)
The final pathway that immediate release naltrexone has been shown to effect is the effect telomeres. Telomeres are inside the nucleus of a cell, our genes are arranged along twisted, double-stranded molecules of DNA called chromosomes. At the ends of the chromosomes are stretches of DNA called telomeres, which protect our genetic data, make it possible for cells to divide, and hold some secrets to how we age and get cancer. Telomeres have been compared with the plastic tips on shoelaces, because they keep chromosome ends from fraying and sticking to each other, which would destroy or scramble an organism's genetic information. Yet, each time a cell divides, the telomeres get shorter. When telomeres get too short, the cell can no longer divide; it becomes inactive or "senescent" or it dies. This shortening process is associated with aging, cancer, and a higher risk of death. Clinical studies have shown that telomere Reduction in Human Liver Tissues with Age and Chronic Inflammation: “Telomere Reduction in Human Liver Tissues with Age and Chronic Inflammation experimental cell research 256(2):578-582 · APRIL 2000 “) Immediate release naltrexone is a proven immunomodulator that helps to reset and rebalance balance of the immune system between the cellular (Th1) and the humoral (Th2) immune systems. Immune balance is regulated through T-helper cells that produce cytokines. The Th1 lymphocytes help fight pathogens that are within cells like cancer and viruses through activation of interferon-gamma and macrophages. The Th2 lymphocytes target external pathogens like parasites, allergens, toxins through the activation of B-cells and antibody production therefore reducing chronic inflammation. Immediate release low dose Naltrexone has been shown to regulate cytokines causing the modulation of TGF-B, leading to a reduction of Th-17, the promoter of autoimmunity. LDN turns off the cells growth that causes autoimmune dysfunction. Findings demonstrate that cancer cell lines express functional TLR4 and TLR9 with possible effects on cancer progression and outcome of BCGbased
(“immunotherapy.J
Biol
Chem.
2013
Nov
15;288(46):33171-80.
doi:
10.1074/jbc.M113.518175. Epub 2013 Oct 4. Inhibition of telomerase recruitment and cancer cell death. Nakashima M, Nandakumar J, Sullivan KD, Espinosa JM, Cech TR”).
Immediate release naltrexone between .01mg and 10mg has been shown in inflammatory bowel diseases to halt inflammation due to the shift of Th1 to TH2 which then allow the telomeres to lengthen but at the same time immediate release naltrexone will inhibit growth causing the telomeres too shorten and when the cells can no longer divide; they die. This shortening process is associated with aging, cancer, and a higher risk of death. Research into the lengthen telomere to reduce inflammation is they lengthening telomeres in all cells including cancer cells. Immediate Release Naltrexone is an immunomodulator and when administered in immediate release format between .01mg and 10mg it will lengthen telomeres in cells therefore reduce inflammation in patients as shown in Crohn’s and IBS patients. LDN is a proven to inhibit cells growth in cancer cells, so LDN could possible be the first drug that could assist in the slowing down of cell death and turn back the aging process. (Telomere extension turns back aging clock in cultured human cells, January 23, 2015 Stanford University Medical Center . Ramunas, E. Yakubov, J. J. Brady, S. Y. Corbel, C. Holbrook, M. Brandt, J. Stein, J. G. Santiago, J. P. Cooke, H. M. Blau. The majority of the currently practiced drug treatments for autoimmune disease, cancer, cardio vascular disease, inflammatory diseases, inflammatory bowel disease, Musculo-skeletal disorders, metabolic disorders and neuro degenerative diseases have significant drawbacks.
The number of patients taking immunosuppressive drugs for the
management of autoimmune inflammatory conditions is increasing. The general practitioner needs to be active in preventing, monitoring and managing the adverse effects of these drugs even long after the treatment has ceased. Monitoring is required because immunosuppressive drugs increase the risks of infection, malignancy, cardiovascular disease and bone marrow suppression. Apart from gastrointestinal disturbances, the nonsteroidal anti-inflammatory drugs have been shown to cause renal toxicity and therefore must be avoided particularly in lupus patients with renal involvement. The antimalarial may cause serious retinopathy, which can occur several years after initiation of therapy. Chronic glucocorticoid therapy is associated with a number of pernicious side effects, including hypertension, excessive immunosuppression and CNS dysfunction.
Immunosuppressive and cytotoxic agent a primary cause or secondary
contributor in many cause bone marrow depression and lead to serious eases, usually as a result of the formation of autoantibodies by the immune system of the organisms, which attack its own cells. Such diseases include, for example, systemic lupus erythematosus, rheumatoid arthritis, autoimmune thyroiditis, autoimmune hemolytic anemia, and certain forms of progressive liver disease. LDN has been shown in to increase bone marrow.
Rheumatoid arthritis in its fully developed form is a symmetrical, inflammatory disease of the synovial lining of peripheral joints, which leads to destructive changes. Although arthritis is the most frequent and prominent manifestation, this is a generalized disease involving many body systems. Pathologically, rheumatoid arthritis is an inflammatory disease involving the immune system. Immune complexes (antigen/antibody) form within the joint and activate the complement system. White blood cells are then attracted into the synovial fluid. These cells phagocytose the immune complexes and in so doing release lysosomal enzymes and other chemical mediators of inflammation. Continued inflammation causes the synovium to proliferate and spread over the joint surface. The thickened synovial tissue, called pannus, releases enzymes, w h i c h erode both cartilage and bone to cause permanent dam age . Rheumatoid arthritis is treated with many of the same pharmaceutical agents used in systemic lupus. Most
patients initially receive nonsteroidal anti-inflammatory drugs,
sometimes together other analgesics. Where the disease is not adequately controlled with these agents, disease-modifying antirheumatic drugs, such, D-penicillamine, as well as steroids and biologic agents. Continuing therapy with any or all of the aforementioned categories of drugs can produce a variety of well-known adverse effects, and none o f these drugs are significantly effective in achieving true remission of the disease in most patients. It is known that inflammatory cells such as polymorphonuclear leukocytes have opiate receptors. The endogenous opioid, endorphin has been shown in both animal and human
studies
to
stimulate
superoxide
radical
production
by
human
polymorphonuclear leukocytes via an opiate receptor. This superoxide production has been shown to be abolished by equimolar concentrations of the opiate antagonist naloxone.(“ B.M. Sharp et al., J. Pharm. Exp. Ther., 242(2):579-582 (1987)�). As used herein, the term human immunodeficiency virus, cancer, cardio vascular disease, inflammatory diseases, inflammatory bowel disease, Musculo-skeletal disorders, metabolic disorders and neuro degenerative diseases refers the daily administration of LDN in a dose between .01 and 10mg has been shown to any disease state or condition associated with the shortening of telomerase causing cell death chronic inflammation and immune dysfunction. SUMMARY OF THE INVENTION It is the object of the present invention to provide a Method for Inducing Sustained Immune Response in humans or animal patient suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, cancer, inflammation, and neurodegenerative diseases which avoids the drawbacks and
disadvantages of prior art and present standard of care drug treatment methods while achieving dramatic symptomatic relief and reducing inflammation levels, systemic autoantibody levels increase production of increasing proliferation and functional activities of CD4+T-cells and CD8+T-cells which will play a role in anti-virus and anti-tumor activities; increasing maturation of dendritic cells which will initiate and intensify T-cell responses; increasing secretion of cytokines such as IL-2, TNF, IL-12 and IFN-γ which will amplify the Tcell response and mediate interaction among immune cells, including the non-opiate receptors like TRL-4 and TRL-9 through forming a modulated and balanced immunity between Th1 and TH2; increasing functions of macrophages, resulting in enhanced cellular immunity through secreting a set of cytokines; and increasing activity of NK cells which have the ability to kill cancer cells and virus-infected cells, lengthen telomerase slowing cell death.
In cancer immediate release naltrexone between .01 and 10mg
enhances
maturation of bone marrow dendritic cells “(BMDCs) Meng J, Meng Y, Plotnikoff NP, Youkilis G, Griffin N, Shan F. -Low dose naltrexone enhances maturation of bone marrow dendritic cells (BMDCs). Int mmunopharmacol. 2013 Dec;17(4):1084”). which is important when patients are undergoing any immunosupression therapy as LDN can held offset the toxic side effects of these treatments. There is no prior art that provides evidence of the difference between Naltrexone at 11mg to 300mg and Naltrexone between .01and 10mg slow release and immediate release between 1mg and 10mg. Nothing that would lead anyone to know the role of immediate release naltrexone between .01mg and 10mg and its effect on telomeres and increase production of increasing proliferation and functional activities of CD4+T-cells and CD8+Tcells which will play a role in anti-virus and anti-tumor activities; increasing maturation of dendritic cells which will initiate and intensify T-cell responses; increasing secretion of cytokines such as IL-2, TNF, IL-12 and IFN-γ which will amplify the T-cell response and mediate interaction among immune cells, including TRL-4 and TRL-9 forming a modulated and balanced immunity; increasing functions of macrophages, resulting in enhanced cellular immunity through secreting a set of cytokines; and increasing activity of NK cells which have the ability to kill cancer cells, increase viral load, effect LR2 and TLR9 to slow down the HIV replication and virus-infected cells, lengthen telomerase slowing cell death. DETAILED DESCRIPTION OF THE INVENTION In accordance with the present invention, immediate release naltrexone between .01mg and 10mg may be administered to patients suffering from humans or animal patient suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, cancer, , cardio vascular disease, inflammatory diseases, chronic inflammation, inflammatory bowel disease, Musculo-skeletal disorders,
metabolic disorders and neurodegenerative diseases in the form immediate release naltrexone tablets, liquids and cream, from about 0.1mg to 8mg in adults and 0.5 to 4.5 mg in children with suitable pharmaceutically-acceptable excipients, binders, sweeteners, coloring agents and other conventional additives. Where high dose Naltrexone and Slow release Naltrexone between .01mg and 10mg and Immediate Release Naltrexone between .01mg and 10mg share commonality" in categories of genes and are considered the same drug the difference in dosing and delivery method (immediate release) difference in the overall response to the immune system. There is a difference in the cell patterns of genes that are altered by the treatment of immediate release naltrexone verses high does naltrexone and slow release low naltrexone between .01mg and 10mg. The differences are important because immediate release naltrexone between .01 and 10mg has as immunomodulator. Since immediate release naltrexone blocks the opiate receptors only for a few hours before it is naturally excreted, what results is a rebound effect; in which both the production and utilization of met (5) enkelphine or opiate growth factor are increased. Once the immediate release naltrexone has been metabolized, the elevated endorphins produced as a result of the rebound effect can now interact with the more-sensitive and more-plentiful receptors and assist in regulating cell growth and immunity. There is not rebound effect with either high dose naltrexone or slow release naltrexone and it is the rebound immunomodulatory effect that effects the treatment of treating patients suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, opportunistic infections, cancer, inflammation, and neurodegenerative diseases The preferred method, immediate release naltrexone is administered to patients in one daily dose of .01 to 10mg. The preferred time for dosing is after 8 PM to 11 PM bedtime but can be used in the morning as well. The method of the present invention not only provides dramatic symptomatic relief for patients suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, cancer, cardio vascular disease, inflammatory diseases, chronic inflammation, inflammatory bowel disease, Musculo-skeletal disorders, metabolic disorders and neurodegenerative diseases for example Alzheimer’s, Asthma, Atopic Dermatitis Addison's disease Alopecia or Alopecia
Areata,
Antiphospholipid Syndrome, Autism, Autoimmune Hepatitis, Autoimmune hemolytic anemia, Autoimmune pancreatitis (AIP), Bullus pemphigoid, Celiac disease, Chronic bullous disease of childhood , Chronic sinusitis, Chronic inflammatory demyelinating Polyradiculoneuropathy (CIDP), Cictricial Regional Pain Syndrome (CRPS),
pemphigoid (CP), Depression, Complex
Crohn's Disease ,Dermatitis herpetiformis (DH),
Dermatomyositis, Evans syndrome, Ehlers Danlos Syndrome (EDS), Fatty liver, Graves' Disease Gullain-Barre syndrome, Hashimoto’s, Inflammatory bowel diseases (colitis, enteritis and ileitis), HIV/AIDS, Insulin-dependent diabetes, Meniere's Disease, Mixed
connective tissue disease or MCTD, Myasthenia, Multiple Sclerosis Multifocal motor neuropath, Neuromyotonia or Isaac's Palindromic Reflex Sympathetic Dystropy (RSD), Rheumatism, Pemphigus vulgaris causes, Pemphigus follaceus PF), Pemphigoid gestationis,
Pernicious
Anemia
Paraneoplastic
Pemphigus
(PNP),
Polymyalgia
Rheumatica, Psoriasis, Psoriatic arthritis, Raynaud's phenomenon, Reactive Arthritis, Retinopathy, Rheumatoid arthritis, Sjogren's syndrome, Systemic lupus erythematosus., Systemic
sclerosis
(scleroderma)
Thromboangiitis
obliterans
,Thyroiditis
with
hypothyroidism, Type I autoimmune polyglandular syndrome (PAS), Type II autoimmune polyglandular syndrome, Varicella-zoster virus, Wegener's granulomatosis Cancer:
Adjunct
to
chemotherapy,
breast,
Hepatoblastoma,
lymphoma,
lymphadenopathy, ovarian, b-cell lymphoma, prostate, pancreatic cancer but has been found to reduce patient’s systemic autoantibody level, increase production of increasing proliferation and functional activities of CD4+T-cells and CD8+T-cells which will play a role in anti-virus and anti-tumor activities; increasing maturation of dendritic cells which will initiate and intensify T-cell responses; increasing secretion of cytokines such as IL-2, TNF, IL12 and IFN-γ which will amplify the T-cell response and mediate interaction among immune cells, including TRL-4 and TRL-9 forming a modulated and balanced immunity; increasing functions of macrophages, resulting in enhanced cellular immunity through secreting a set of cytokines; and increasing activity of NK cells which have the ability to kill cancer cells and virus-infected cells, lengthen telomerase slowing cell death potentially leading to a true remission in the course of the disease. The following examples provide a detailed illustration of the method of the present invention. These examples are not intended to limit or restrict the scope of the invention in any way. CLAIMS 1.
Method for Inducing Sustained Immune Response in humans or animal patient suffering from human immunodeficiency virus (HIV) acquired immune deficiency syndrome (AIDS, autoimmune disease, cancer, inflammatory disease, chronic
inflammation, and
neurodegenerative diseases which comprises the steps of administering by a pharmacologically effective mode to such patient an effective dosage within a range corresponding to about 0.1mg to about 8mg of immediate release naltrexone, of an essentially pure opiate receptor antagonist which within said dosage range exerts an opiate receptor blocking action towards Mu opiate receptors, that works on the body’s natural opioid system to restore immune balance between TH1 and TH2. The restoration of balance involved the opiate receptor, tolling receptor, telomeres, as well as P14 and P16, TRL-4, TRL-9, HHV-6. Immediate release naltrexone in a dose between .01mg and 10mg has been shown to affect all of these receptors and it is believed with further testing Immediate
release naltrexone in a dose between .01mg and 10mg will prove to effective on other receptors that effect immune health. The method of claim 1, wherein said opiate receptor antagonist is immediate release naltrexone and is different than either Naltrexone in high dose over 10mg or slow release naltrexone at .01mg to 10mg. Where Immediate Release Naltrexone at a dose between . 01mg to 11mg and high dose naltrexone over 11mg and Slow Release Naltrexone between . 01mg and 10mg share commonality" in categories of genes and are considered the same drug the only difference is delivery time and dosing. The difference in the overall immune actions are different when taken in the prescribed dose.
2.
The method of claim 1 wherein said dosage is administered substantially between the hours of 8:00 p.m. and 11:00 p.m. in order to achieve substantially enhanced effectiveness in releasing endorphins, increase the production of cytokines into the system of the human being treated.
3.
The method of claim 2 wherein said dosage is administered generally between the hours of 12:00pm and 2:00p.m. A method for promoting a sustained increased level of T-cell production in immunocompromised subjects in which immediate release naltrexone is administered according to a dose schedule.
4.
A method of treatment of immunocompromised patients which includes the administration of immediate release naltrexone, between .01mg and 8mg either alone or in conjunction with other therapies, in an initial dosage regimen, as necessary to maintain sustained immune system response.
5.
The methods of treatment of claims 1 or 2, wherein the other therapies include vaccine, cytokine, antiviral, antibiotics, antifungal, antiparasite and anti-tumor therapies.
6.
The method of claim 2, wherein the initial dose (tablet, capsule, liquid or cream) regimen is a single dose daily as long as necessary to sustain immune balance.
7.
A method of treatment of cancer by administering immediate release naltrexone between . 01mg and 8mg according to a dose schedule.
8.
A method of treatment of cancer which includes the administration of immediate release naltrexone, between .01mg and 8mg according to a dose schedule either alone or in conjunction with other therapies, as necessary to maintain sustained immune system response.
9.
A method of treating cortisol-induced immunosuppression in a subject by treating said subject with a dose regimen of immediate release naltrexone, between .01mg and 8mg according to a dose schedule.
10.
A method of inhibiting cortisol-induced suppression of cytokine production in a subject by treating said subject with a dose regimen of immediate release naltrexone between .01mg and 8mg according to a dose schedule
11.
A method of inhibiting a cortisol-induced reduction of gene transcription of IL2 in a subject by treating said subject with a dose regimen of immediate release naltrexone between . 01mg and 8mg according to a dose schedule
12.
A method of inhibiting cortisol-induced down-regulation of cytotoxic cells or NK lymphocytes in a subject by treating said subject with a dose regimen of immediate release naltrexone between .01mg and 8mg according to a dose schedule
13.
A method of treating a human patient suffering from a virus infections infection which comprises the step of administering by a pharmacologically effective mode to such patient a therapeutically effective dose consisting of immediate release naltrexone between .01mg and 8mg according to a dose schedule
14.
The method of treatment Neurodegenerative diseases, treating said subject with a dose regimen of immediate release naltrexone between .01mg and 8mg according to a dose schedule has shown to effect the products of Cytokines, and effect Chemokines (CX3Cl1) Nurotramsimitters and have a direct effect on the Macrophage.
15.
A method for increasing the length of telomere in treating chronic inflammation in particular from depression, Crohn’s Disease, inflammatory bowel diseases and Cardiovascular Disease by administering treating said subject with a dose regimen of immediate release naltrexone between .01mg and 8mg according to a dose schedule has been shown to it has been shown to cause telomere cause telomere dysfunction and accelerates ageing an effect on length of telomerase by decreasing inflammation.
EXAMPLE Human immunodeficiency virus (HIV) Clinical Trials
A single blind 90 day randomized bridging clinical trial was conducted in Nigeria to evaluate the impact of immediate release naltrexone 4.5mg single oral dose on asymptomatic HIV+ adults undergoing antiretroviral (ART) treatment with CD4 counts below 360 average. The differences in CD4 count, CD4%, hemoglobin, viral load, interferon alpha, and standard chemistry panel were measured between treated versus non-treated groups four times throughout the study. The results showed an improvement in CD4 count in the treatment group was 53 that were significantly greater than the control group (54 subjects) at 3 months with an increase of 44%. Improvement in CD4% in the treatment group was observed throughout treatment, and the increases were statistically significant. In addition to the changes in CD4 count patients saw an increase in BMI, reduction in opportunistic infections. These data presented herein on patients who have been placed on immediate release naltrexone between .01 and 10mg who have HIV/AIDS show that it has the ability to be an effective immune-enhancing agent specifically in this disease by increasing or stabilizing a patient’s CD4 count or by providing a decline in IFN-α levels. When used alone, it appears to slow and/or stop the progression of the disease. When used in combination with antivirals, immediate release naltrexone between .01mg and 10mg appears to accelerate immune system healing and increase CD4 levels. (Dr. Richard Afonja and Noreen Griffin December 2015)
A single blind nine-month randomized clinical trial was conducted in Mali to evaluate the impact of immediate release naltrexone at 3mg on asymptomatic HIV+ adults undergoing antiretroviral (ART) treatment with CD4 counts below 350 cell/mm3. The differences in CD4 count, CD4%, hemoglobin, viral load, interferon alpha, and standard chemistry panel were measured between treated versus nontreated groups five times throughout the study. .
The results showed an
improvement in CD4 count in the treatment group (51 subjects) that was significantly greater than the control group (49 subjects) at 6 months (p = 0.041) and marginally at 9 months (p = 0.067). Improvement in CD4% in the treatment group was observed throughout treatment, but these increases were not statistically significant (Traore AK. et al., Sept 2011). The results were effected by the fact the product was compounded and was dosed at 3mg rather then 4.5mg
A single blind nine-month randomized clinical trial was conducted in Mali to evaluate the impact of IMMEDIATE RELEASE NALTREXONE (LDN) on asymptomatic HIV+ adults undergoing antiretroviral (ART) treatment with CD4 counts below 350 cell/mm3. The differences in CD4 count, CD4%, hemoglobin, viral load, interferon alpha, and standard chemistry panel were measured between treated versus nontreated groups five times throughout the study. The results showed an improvement in CD4 count in the treatment group (51 subjects) that was significantly greater than the control group (49 subjects) at 6 months (p = 0.041) and marginally at 9 months (p = 0.067).
Improvement in CD4% in the treatment group was observed
throughout treatment, but these increases were not statistically significant (Traore AK. et al., Sept 2011). The results on this trial were not an effective because the immediate release naltrexone used was compounded and was only 3mg rather then 4.5mg which has been shown to be the most effective dose.
Dr. Bihari and his colleagues conducted a 12-week, placebo-controlled trial of IMMEDIATE RELEASE NALTREXONE (LDN) from 1985-1986 in 38 patients with AIDS. Patients were administered 3.0 mg IMMEDIATE RELEASE NALTREXONE (LDN) daily at bedtime. Patients who participated in this trial showed a significant difference in the incidence of opportunistic infections with 5 out of 16 patients (31%) on placebo developing opportunistic infections in comparison to 0 of the 22 patients in the immediate release naltrexone (LDN) group. Other difference between placebo and
immediate release naltrexone (LDN) treated patients included: lymphocyte mitogen responses declined on placebo and not on immediate release naltrexone; pathologically elevated levels of acid-labile alpha interferon declined significantly in the patients on immediate release naltrexone and not in those patients on placebo (Bihari et al., Sept. 1996).
A study of 55 patients two are trial one with Two Groups One on Epivir and AZT and one group on Epiviver and AZT neither group had taken AZT before the study. The Glaxo patients on Epivir and AZT experienced an average rise of 40 CD4's at 6 months. This represents an 11.3% increase. The patients on Epivir, AZT and immediate release 4.5mg naltrexone experienced an average rise of 106 CD4's at 6 months, representing a 128% increase. All 19 of the patients in the naltrexone group had increases of at least 30%. In addition there was, in all but one, a significant increase in energy, appetite and mood. In several underweight patients there were weight gains of 10 to 50 pounds in the first 2 months with no opportunistic infection. New England Journal of Medicine of December 21, 1995 (vol. 333, number 25, pg. 1662) reported by an investigator working for Glaxo.
Cancer:
Twenty-nine of the patients had Kaposi's sarcoma (K.S.), six previously had a major opportunistic infection (O.I.) and three had both O.I. and K.S. The mean time of the 38 patients from AIDS diagnosis to admission into the study was 7.6 months. Thirtyone of the 38 patients had a baseline absolute T4 count of less than 300/ml. immediate release naltrexone was administered at a dose of 1.75 mg nightly at bedtime. During the 3-month double-blind period, a significant drop in elevated levels of serum alpha interferon (IFN-α) was observed in those patients receiving LDN compared with the placebo patients (p < .01). After completion of this double blind period, all of the 38 patients were placed on immediate release naltrexone. Twenty-three of the 38 patients showed a marked decline in IFN-α levels (from means of 144.9 IU. to 11.0 IU. over a 12-month period) while the remaining 15 did not show such a decline. Nineteen of the 23 (83%) who showed a decline in IFN-α survived while only 2 of the 15 (13%) who did not show such a decline survived (p < .01). No side effects were noted during the conduct of this trial (Bihari et al., June 1988).
This study aimed to investigate its effect on hematologic cancer patients. This was a randomized controlled trial assessing quality of life in patients with hematologic
malignancies from a single institute. Patients were allocated into two study arms and in addition to their routine treatment received either daily immediate release naltrexone 3 mg capsules (treatment group) or 3 mg starch (placebo group) and were followed up for 5 months. Quality of life was measured using the EORTC QLQC30 in four points in time (at admission, 1, 3 and 5 months follow-up). Data were analyzed to compare quality of life in two groups. Totally, 89 patients were studied (45 in treatment group and 44 in placebo group). There were no significant differences between two groups either in demographic and clinical characteristics or in baseline quality of life scores. However, at 1 month, 3 and 5-month follow-up assessments significant differences were observed. In one month follow-up two groups were significantly different in social functioning (p<0.05) indicating a better condition in the treatment group. In the 3-month follow-up, social functioning, role functioning, nausea and vomiting and appetite loss were better in the treatment group (all p-values <0.05). In the 5-month follow-up, physical functioning, social functioning, role functioning, global quality of life, nausea and vomiting and appetite loss were significantly better in the immediate release naltrexone group. Immediate release naltrexone between .01 to 10mg is an effective drug in improving quality of life in patients with hematologic cancers. Most importantly, there were no changes in the blood laboratory tests with immediate release naltrexone. Compared to standard chemotherapy that reduces the blood count from bone marrow toxicity, white blood cell, red blood cell and plate count remained stable with immediate release naltrexone.
Treatment of advanced pancreatic cancer with Opioid Growth Factor in 24 patients Clinical benefit response was experienced by 53% of OGF-treated patients compared to historical controls of 23.8% and 4.8% for gemcitabine and 5fluorouracil (5-FU), respectively. Of the subjects surviving more than eight weeks, 62% showed either a decrease or stabilization in tumor size by computed tomography. The median survival time for OGF-treated patients was three times that of untreated patients (65.5 versus 21 days, p < 0.001). No adverse effects on hematologic or chemistry parameters were noted, and quality of life surveys suggested improvement with OGF.
This trial shows that immediate release
naltrexone can slow or cause cell death.
A 46-year-old man diagnosed in October 2002, with poorly differentiated adenocarcinoma of the pancreas with metastases to the liver, began intravenous treatment with α-lipoic acid (ALA) 300 to 600 mg two times per week, 4.5 mg immediate release naltrexone (LDN) once per day at bedtime, oral ALA (600 mg/day), selenium (200 µg two times per day), and silymarin (300 mg four times a
day), including a strict dietary regimen along with a stress-reduction and exercise program. The average length of survival after diagnosis of pancreatic cancer ranges from 3 to 6 months; however this patient, at the time this article was written in 2006 showed comparatively stable disease for more than a 3-year period and an improved quality of life (Berkson et al., 2006).
A 61-year old man was diagnosed with biopsy-proven Follicular Lymphoma (FL). His initial physical examination and PET/CT scan showed multiple large, metabolically active, pathologic lymph nodes. After 6 months of receiving immediate release naltrexone (LDN) daily in the evening, in addition to a prescribed healthy diet, a nutritional supplement regimen, and intravenous α-lipoic acid (ALA). This patient however, did not remain compliant with the diet, the nutritional supplement, or the ALA. Thus the achievement of clinical and radiological remission was deemed to be due to the IMMEDIATE RELEASE NALTREXONE (LDN) alone. In 2007 when this report was published, per telephone communication from the patient’s wife, the patient remains asymptomatic from his disease, 1 year after his last CT/PET imaging (Berkson et al., 2007).
Three patients presented to the same clinic and were all treated with the same ALA+ immediate release naltrexone (LDN) protocol. The patients presented with the following diseases and had the following outcomes:
Adenocarcinoma of the
pancreas with metastases to the liver. This patient is alive and well 39 months after presentation of disease and initiation of ALA+ immediate release naltrexone (LDN) therapy. Adenocarcinoma of the pancreas with metastases to the liver, presented with the same diagnosis as the above patient. After 5 months of ALA+ immediate release naltrexone (LDN) therapy, a PET scan demonstrated no evidence of disease.
Pancreatic cancer with liver and retroperitoneal metastases, with a history of B-cell lymphoma and prostate adenocarcinoma. After 4 months of ALA+ immediate release naltrexone (LDN) therapy his PET scan demonstrated no signs of cancer (Berkson et al., 2009).
Two Case Studies:
Hepatoblastoma is the most common liver malignancy in
children, typically diagnosed before age 2. The survival rate for hepatoblastoma has
increased dramatically in the last 30 years, but the typical chemotherapeutic agents used for treatment are associated with significant toxicity. In this report, the authors present two cases of hepatoblastoma treated with surgical resection and a novel biotherapeutic regimen that included opioid growth factor (OGF). Case #1 is an infant diagnosed with a large mass on prenatal ultrasound. After subsequent diagnosis of hepatoblastoma, she was treated with one course of neoadjuvant chemotherapy at approximately 1 week of age. Following significant complications from the chemotherapy (neutropenic fever, pneumonia and sepsis), the patient's parents declined further chemotherapy, and the infant was treated with surgical resection and opioid growth factor (OGF)/ immediate release naltrexone. She is currently at close to 10 years disease-free survival. Case #2 is a child diagnosed with a liver mass on ultrasound at 20 months of age, later biopsy-proven to represent hepatoblastoma. Due to existing co-morbidities including autosomal recessive polycystic kidney disease and hypertension, and indications from the biopsy that the tumor might be insensitive to chemotherapy, the parents elected not to proceed with neoadjuvant chemotherapy. The patient was treated with surgical resection and OGF/IMMEDIATE RELEASE NALTREXONE (LDN), and is currently at more than 5 years disease-free survival. This case series highlights the need for less toxic treatment options than conventional chemotherapy. Modulation of the OGF-OGF receptor axis represents a promising safe and therapeutic avenue for effective treatment of hepatoblastoma. Rogosnitzky M, Finegold MJ, McLaughlin PJ, Zagon IS. Invest New Drugs. 2013 Aug; 31(4): 1066-70.
ď&#x201A;ˇ
85-year-old man diagnosed with stage 3-stomach cancer prognosis 6 months to live on March 15, 2007 and started immediate release naltrexone 4.5mg on March 28, 2007. In addition to immediate release naltrexone patients received chemotherapy and kidney stents inserted. Immediate release naltrexone was started after two rounds of chemotherapy in September 2007 patient had a CT scan, that showed tumors shrunk in half and removed the kidney stents. In December of 2007 patients was determined to be in remission and stable. In March 2008 another CT scan was done and tumors had shrunk in half, and a third scan was done in March of 2009 and tumors were stable. Patients from 2007 through 2009 continued on 4.5mg of immediate release naltrexone.
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75 year old woman diagnosed with stage 4 pleural mesothelioma in December of 2008 and patients after consult with two other doctors it was determined due to the state of the diseases and other health issues to watch the tumors and not do chemotherapy. Prognosis was 6 to 12 months. Patient started 4.5mg nightly and received on other treatment but did change diet. Two CAT scans Feb 2009 and 2010
both showed no measurable growth of tumors. Immediate release naltrexone between .01mg and 10mg has been shown to stabilize or show the growth of tumors.
A 69 year old man diagnosed with stage 4-colon cancer, 2007 which had spread to his lungs and liver, they removed 40% of his colon and began a round of chemotherapy and three surgeries removed 40% of his colon, half is his right lung and 75% of his liver. During the next 18 months received 47 weeks of chemotherapy (a combination of 4 chemo drugs at once). Was going to stop chemotherapy due to toxic side-effects but started IMMEDIATE RELEASE NALTREXONE in June of 2007 he started 4.5mg nightly of IMMEDIATE RELEASE NALTREXONE immediately and was able to complete the entire protocol without any major side effects at all. Patient had scans every six months and continued cancer free until June of 2015 when they found a small growth in his right lung which they removed with no need for chemotherapy or radiation, patients
87 years old male was diagnosed with stage 3 prostate cancer which he was originally treated for 5 years before began 3 rounds of Docetaxel (Taxotere®) he was prescribe 4.5mg of IMMEDIATE RELEASE NALTREXONE which he took nightly and has continued with since the completion of the protocol. Patient was able to withstand the chemotherapy and his blood work stayed stable throughout the protocol, and maintained his weight, and overall quality of life was much better.
Parkinson Disease A eight-week clinical study in which 48 PD patients diagnosed with one or more ICDs that developed during PD and in the context of dopamine agonist (DA) treatment will receive either naltrexone or placebo treatment in a blinded fashion. Recruitment will be such that all four common ICDs in PD (compulsive gambling, buying, sexual behavior and eating) are equally represented. Patients will be seen every other week during the course of the study, and treatment response and tolerability will be assessed at each visit. The results of this study were negative for the efficacy of immediate release naltrexone at 4.5mg for the treatment of impulse controls disorders (such as compulsive gambling, buying, sexual behavior and eating) in Parkinson’s disease (PD) using a clinician rating of general improvement, which was the primary outcome measure for the study. However, using a patient-completed, PD-specific assessment of impulse control disorder symptom severity, naltrexone treatment was associated with a significant decrease in symptoms compared with placebo treatment. The results of this preliminary study support further research with naltrexone for the treatment of these disorders in PD.
63 year old woman diagnosed with Parkinson disease in October 2008 during the next three years doctors prescribed Sinemet, Requip caused major side effects, falling asleep while driving, and Symmetrel had to stop work, while they helped offer relief from her symptoms. In June of 2011 patient started on 4.5mg of IMMEDIATE RELEASE NALTREXONE and over the next 6 month was able to titrate off all other medications and the majority of patient’s symptoms have subsided.
72 year old male diagnosed with Parkinson Disease in October 2009 suffered brain fog, shaking on right hand, very tired started 3mg of IMMEDIATE RELEASE NALTREXONE in August of 2013 as none of the standard treatments were not helping or the side effects were not acceptable. Patient continues on IMMEDIATE RELEASE NALTREXONE today as his only treatment patients confirms brain fog gone and shaking is less,
66 year old male diagnosed with Parkinson Disease in November of 2011, patient suffered from hand/arm tremors, jaw/tongue tremors, memory impairment, lack of cognitive function, sleep disorder mask like appearance, patient started on 1.5mg of IMMEDIATE RELEASE NALTREXONE titrating up to 3mg. Major improvement within first 2weeks at 1.5mg jaw/tongue tremors stopped and by 2nd month at 3mg patients sats mental function restore, hand/arm tremors have lessened and patient has returned to work patient takes on PD medications and continues on IMMEDIATE RELEASE NALTREXONE.
Autism
155 children participated in 10 studies; 27 received placebo. Of the 128 that received naltrexone 98 (77%) showed statistically significant improvement in symptoms of irritability and hyperactivity. Side effects were mild and the drug was generally well tolerated.
Randomized, double blind, placebo-controlled study with immediate release naltrexone in the treatment of autism. Eight of 13 subjects improved in two or more settings. Changes in parent measures (CGI, Conners Impulsivity-Hyperactivity Factor, and SE-Restlessness) and Teacher CGI achieved statistical significance. Teacher SERestlessness and initiation of communication in the clinic showed a trend toward improvement. Actometer readings improved in two children who were very active at baseline.
Opioid-immune interactions in autism: behavioral and immunological assessment during a double-blind treatment with naltrexone. The behavioral improvement was accompanied by alterations in the distribution of the major lymphocyte subsets, with a significant increase of the T-helper-inducers (CD4+CD8-) and a significant reduction of the T-cytotoxic-suppressor (CD4-CD8+) resulting in a normalization of the CD4/CD8 ratio. Changes in natural killer cells and activity were inversely related to plasma beta-endorphin levels. It is suggested that the mechanisms underlying opioid-immune interactions are altered in this population of autistic children and that an immunological screening may have prognostic value for the pharmacological therapy with opiate
9 year old boy diagnosed with Autism & ADHD in June of 2007 no eye contact and chronic stomach pain started IMMEDIATE RELEASE NALTREXONE in 2009 started at . 1 mg for 2 weeks then 2 mg 2 weeks 3mg more TICS for month as on Ritaline, Risperdal, Dexamine, today only takes IMMEDIATE RELEASE NALTREXONE good eye contact and almost on pain.
4 year old girl diagnosed with Autism in 2008 was continually sick started IMMEDIATE RELEASE NALTREXONE in Oct 2009 side effect a little constipation 5ml at bedtime celxia and have continued celxia plus IMMEDIATE RELEASE NALTREXONE has not been sick since starting IMMEDIATE RELEASE NALTREXONE and language skills have improved. This is important as many children with Autism suffer from IBS.
5 year old boy diagnosed with Autism in 2007 with autoimmune problems, very low NK activity, started IMMEDIATE RELEASE NALTREXONE 3mg in August of 2009, hyperactivity increased for the first three weeks. Over the next months social behaviors skyrocketed after IMMEDIATE RELEASE NALTREXONE. Started requesting "play dates" with friends when that had never been a desire before. Developed real friendships after starting IMMEDIATE RELEASE NALTREXONE in addition to IMMEDIATE RELEASE NALTREXONE he takes Nystatin, Fluconazole and supplements continues taking IMMEDIATE RELEASE NALTREXONE today
Autoimmune Hepatitis
Hepatic Methionine-enkephalin may interfere with response to antiviral therapy in chronic hepatitis sought to investigate the expression of the immunoreactivities of Met-enkephalin and of the δ-opioid receptor 1 (DOR1), to which Met-enkephalin
binds, preferentially, in liver samples from 23 patients with chronic hepatitis C who had undergone antiviral therapy. Twelve patients obtained a sustained virological response, and 11 patients were relapsers after or nonresponders to treatment. Among the 12 patients with sustained virological response, one patient (8.3%) expressed MEIR and another one expressed DOR1 immunoreactivity (8.3%), whereas none of the patients expressed both immunoreactivities. Among the group of nonresponders/relapsers, one patient expressed MEIR (9%), two patients expressed DOR1 immunoreactivity (18.2%), and seven patients expressed both (63.6%). The difference between responders and nonresponders in the expression of both immunoreactivities was significantly different (P<0.001).
63 year old woman diagnosed January of 2012 with Hepatitis C and Diabetes started taking IMMEDIATE RELEASE NALTREXONE January 2013 4mg once a day in the morning.
Was being controlled by Prednisone but was having increasing side
effects, and decided to try IMMEDIATE RELEASE NALTREXONE. Patients no longer takes prednisone or other immunosupression drugs, continues to take 4mg in morning
63-year-old female diagnosed with Autoimmune Hepatitis – Type 1 November of 2008 was taking Prednisone, Azathioprine, and 6MP, Cellcept, Budesonide. Patients was having Liver function tests monthly and they were elevated and rising monthly. Patient had vivid dreams and mild indigestion in the first two weeks. Patients for the first year had monthly blood tests hepatitis is under control with only 4.5mg IMMEDIATE RELEASE NALTREXONE nightly
57 year old male diagnosed with Hepatitis C October 2002 patients suffered from fatty liver, chronic hepatitis C, elevated liver enzymes, sever fatigue, IBD and Fibromyalgia and was treated with a number of different immunosupression drugs including prednisone, Patient started IMMEDIATE RELEASE NALTREXONE in February of 2009 and stopped all other medication and recent ultrasound shown No fatty liver, Liver enzymes dropped to normal, HCV viral load dropped from over a million in January 2009 to 49,000 in May 2009. On my May 2010 labs, it had dropped down to 11.400. . Patient continues to be stable has more energy, IBS is no longer a problem and fibromyalgia is greatly improved.
6 year old girl diagnosed with Hepatitis B failed standard treatment started 1mg immediate release IMMEDIATE RELEASE NALTREXONE within one month viral load decreased from 59.2 million to 53,000, ALT/AST decreased to normal. Within 7 months Sero-conversion to negative antigens and positive antibodies, Viral load 551 additional benefits included resolutions of eczema.
52 year old man diagnosed with Hepatitis C & stage 4 cirrhosis of the liver after one year of intensive alpha lipoic acid, glutathione therapy, liver enzyme levels normal, Viral load still high and patient on transplant list Started Immediate release IMMEDIATE RELEASE NALTREXONE 4.5mg March of 2011 Viral load dropped from 24.4 million to 11.9 million by May of 2011 by August of 2011 viral load dropped to 8.3 million and has continued to drop through 2012
Blepharitis. Blepharitis.
62-year-old male diagnosed with blepharitis at age 45 was treated with various drugs including Antibiotic ointment and Restasi. Patient began treatment with 3mg of IMMEDIATE RELEASE NALTREXONE February of 2014 and realized that his blepharitis has been cured for the first time in many years.
Complex regional pain syndrome (CRPS)
A 48 year-old male veteran sustained an injury to his right leg in 2006. While undergoing aqua-therapy, he injured his right great toe, which subsequently became infected. Following drainage of an abscess and removal of the great toe’s nail, the patient developed the following CRPS symptoms in his right lower extremity: swelling, allodynia (pain to normal touch), color change, temperature change, and some weakness. By 2007, the patient developed moderate CRPS symptoms in his upper extremities. In 2008, he developed blisters and skin ulceration in his right lower extremity (Fig. 1). At this time, the patient was being treated with opioids, pregabalin, and duloxetine. By 2009, the patient’s pain had become severe enough that he could not ambulate without assistance. He developed muscle spasms in the right upper extremity. In 2010, he underwent a cardiac bypass surgery for coronary artery disease. His CRPS symptoms became widespread after this surgery, spreading to his upper chest, upper arms, and forearms. In 2011, the patient developed significant dystonic spasms to both upper extremities, resulting in hyperextension of his fingers. From 2008 to 2012, the patient underwent multiple treatments with anticonvulsants, antidepressants, physical therapy, psychotherapy, topical and systemic analgesics, including but not limited to opioids. The patient also currently has diabetes mellitus type II, hypertension, hyperlipidemia, as well as coronary artery disease.
In August of 2011, the patient began low-dose intravenous ketamine infusions. He reported a good initial response, but the relief was not sustained. He continued to have ketamine booster infusions at intervals of 4 to 6 weeks. Although the patient engaged in aggressive physical therapy during this time, his maximum interval of relief from pain following a given ketamine infusion decreased to an interval of 3 weeks. In January 2012, his use of the opioid oxycodone was changed to tapentadol.
This narcotic was removed for 1 week prior to starting low-dose naltrexone, which was started and maintained at 4.5 mg per day (1 dose at night). Additional medications included: metformin, tramadol, valsartan, cloazepate, simvastatin, fish oil, and vitamin C.
Immediately before IMMEDIATE RELEASE NALTREXONE
treatment, the patient had patchy areas of allodynia to the medial and dorsal aspect of his right foot, extensive areas of dysesthesia in his right lower extremity below the knee and heel of his foot, as well as bilaterally dysesthesia in the upper extremities. There were significant color and temperature changes in the right foot compared to the left foot, as well as pitting edema in the right foot. A triple-phase bone scan revealed significant reuptake in the right foot, characteristic of CRPS. By March of 2012, the patient’s requirements for the lower dose intravenous ketamine infusions were not as frequent (6 week intervals, pain spikes not as high). The patient recovered from CRPS flares more quickly, felt more energetic, and tolerated pain better. He became physically more active, and his sleep improved significantly. Within 2 months after starting IMMEDIATE RELEASE NALTREXONE, the patient’s dystonic spasms discontinued, although he still had moderate pain in both upper extremities. The patient was able to walk without a cane (Fig. 2b), which he had used continuously since 2006. His pain was an average of 8 to 10 on the Numeric Rating Scale (NRS) before starting IMMEDIATE RELEASE NALTREXONE. It dropped down to an average of 5 to 6 on the NRS after starting IMMEDIATE RELEASE NALTREXONE. After IMMEDIATE RELEASE NALTREXONE therapy, the patient’s pain symptoms have reduced in severity, but not in their distribution. His current mood state is good. No side effects of IMMEDIATE RELEASE NALTREXONE were noted.
A female patient, currently 12 years old, has a genetic disorder, Ehlers-Danlos Syndrome (EDS) hypermobility type 1, dysautonomia, non-epileptic seizures, chronic gastritis, mitochondrial dysfunction, asthma, vision loss, thyroid tumor and anticardiolipin antibodies. As a result of her EDS, the patient has had repeated dislocations of her right shoulder, as well as her right ankle. The patient first developed CRPS in her lower right extremity in 2008. In 2009, the patient developed dystonic muscle spasms in the upper extremities, which were interpreted by her physicians as evidence of a conversion disorder. The patient was first seen by one of us (PC) in February of 2011. Her symptoms of CRPS included color change, increased temperature in the right foot (90 °C) versus (82 °C) in the left foot, allodynia over the dorsum of right foot, and patchy areas of dysesthesia over her right leg. She also had areas of allodynia and dysesthesia in the left lower extremity and both upper extremities, as well as distorted nails on the right foot. When first seen, the patient’s medications were levetiracetam, midodrine, baclofen, trazodone, diphenhydramine, lansoprazole, budesonide, levalbuterol, L-Carnitine, coenzyme Q10, vitamin D, vitamin C, magnesium, and vitamin B complex. She rated her pain on a NRS (Numerical Rating Scale) as 8/10 at its lowest and 10/10 at its worst. In early 2011,
the patient experienced a subluxation of her right ankle. The lower right leg and ankle subsequently developed fixed dystonia, with plantar flexion and varus. Fixed dystonia, allodynia, and vasomotor abnormalities in the right lower extremity of a CRPS patient (panel a) remitted following treatment with a low-dose naltrexone. , No symptoms and signs of CRPS after IMMEDIATE RELEASE NALTREXONE treatment. Two months after surgical reinforcement of the right ankle for Ehlers-Danlos Syndrome (EDS) In June 2011, the patient was started on low dose naltrexone (IMMEDIATE RELEASE NALTREXONE) of 3 mg once a day and ketamine troches (sublingual) 10 mg on as needed basis. The IMMEDIATE RELEASE NALTREXONE was increased to 4.5 mg per day, 4 weeks after starting it. IMMEDIATE RELEASE NALTREXONE was started as a lower dose to gauge tolerability. She tolerated the IMMEDIATE RELEASE NALTREXONE very well with no reports of adverse effects. Her pain scores dropped from NRS (7–10)/10, to (3–5)/10. She also reported a decrease in allodynia, as well as a decrease in sensitivity to touch and temperature change. There was no effect on the dystonia. Two months after starting IMMEDIATE RELEASE NALTREXONE, she underwent 400 units of botulinum toxin, injections to the right gastrocnemius group of muscles with minimal relief of her dystonia. The right lower extremity was placed in an above knee cast for 6 weeks. Several weeks after the cast was removed, the patient subluxated her right ankle again. She underwent a 400 units injection of botulinum toxin, and a cast was applied again. The patient used ketamine troches (10 mg) for 3 weeks after the IMMEDIATE RELEASE NALTREXONE was started, as needed for pain. She was taking ketamine troches on as needed basis for acute flare-ups of her CRPS pain. This was limited to no more than 30 mg of ketamine troches per day. The patient progressively reduced her use of ketamine troches 3 weeks after starting IMMEDIATE RELEASE NALTREXONE, and by 8 weeks was taking them rarely. In December of 2011, she underwent percutaneous pinning of the right ankle to stabilize the joint. The pins were removed 6 weeks later and the ankle joint subluxated again. In February of 2012, the patient underwent reinforcement to the right ankle with cadaver ligaments. She continued to be on low dose naltrexone during this time, except for 4 perioperative days, during which the IMMEDIATE RELEASE NALTREXONE was discontinued. As per institutional protocol, IMMEDIATE RELEASE NALTREXONE was stopped for 24 h before surgery. After surgery, she was given oral opioids (hydrocodone with acetaminophen) for 1 week. The oral opioids were then discontinued, and IMMEDIATE RELEASE NALTREXONE treatment was resumed 24 h, after her last dose of opioid. The patient noticed a decrease in her post-operative pain, ranging from (4–6)/10, 3 weeks after resuming IMMEDIATE RELEASE NALTREXONE. Skin discoloration and allodynia could not be assessed after the surgery because her leg was in a cast. At the time of cast removal, the patient’s lower leg and ankle had a normal range of motion, indicating a remission of the leg’s fixed dystonia (Fig. 3b). The leg had a slight red color at the
time of cast removal, but no allodynia. Ten months after surgery, the patient’s gait was normal. Remarkably, the patient did not experience any spread of her CRPS, despite undergoing multiple invasive procedures, including surgery. One of the known triggers for a CRPS flare-up, or spread of CRPS symptoms, is trauma (Schwartzman et al. 2009; van Rijn et al. 2011). The patient still has a chronic shoulder dislocation, associated with her EDS. However, her CRPS symptoms have resolved completely. The patient has been maintained on IMMEDIATE RELEASE NALTREXONE for 18 months. No side effects of IMMEDIATE RELEASE NALTREXONE have been noted. Crohn’s Disease
A pilot clinical trial was conducted in children with moderate to severe Crohn's disease. Fourteen subjects with a mean age of 12.3 years (range, 8 to 17 y) were enrolled. Children were randomized to placebo or immediate release naltrexone (0.1 mg/kg) orally for 8 weeks followed by open-labeled treatment with 8 additional weeks of naltrexone. Safety and toxicity were monitored by physical examinations and blood chemistries. Clinical activity was assessed by the Pediatric Crohn's Disease Activity Index (PCDAI) and Quality of life was monitored by the Impact III survey. Oral immediate release naltrexone was well tolerated without any serious adverse events in children with moderate to severe Crohn's disease. PCDAI scores significantly decreased from pretreatment values (34.2±3.3) with an 8-week course of naltrexone therapy (21.7±3.9) (P=0.005). Twenty-five percent of those treated with naltrexone were considered in remission (score ≤10) and 67% had improved with mild disease activity (decrease in PCDAI score by at least 10 points) at the end of the study. Systemic and social quality of life improved with naltrexone treatment (P=0.035).
Eligible subjects with histologically and endoscopically confirmed active Crohn's disease activity index (CDAI) score of 220-450 were enrolled in a study using 4.5mg naltrexone/day. Infliximab was not allowed for a minimum of 8 weeks prior to study initiation. Other therapy for Crohn's disease that was at a stable dose for 4 weeks prior to enrollment was continued at the same doses. Patients completed the inflammatory bowel disease questionnaire (IBDQ) and the short-form (SF-36) quality of life surveys and CDAI scores were assessed pretreatment, every 4 weeks on therapy and 4 weeks after completion of the study drug. Drug was administered by mouth each evening for a 12-week period. RESULTS: Seventeen patients with a mean CDAI score of 356 +/- 27 were enrolled. CDAI scores decreased significantly (P=0.01) with LDN, and remained lower than baseline 4 weeks after completing therapy. Eighty-nine percent of patients exhibited a response to therapy and 67%
achieved a remission (P < 0.001). Improvement was recorded in both quality of life surveys with LDN compared with baseline. No laboratory abnormalities were noted.
Forty subjects with active Crohn's disease were enrolled in the study. Randomized patients received daily oral administration of 4.5-mg naltrexone or placebo. Providers and patients were masked to treatment assignment. The primary outcome was the proportion of subjects in each arm with a 70-point decline in Crohn's Disease Activity Index score (CDAI). The secondary outcome included mucosal healing based upon colonoscopy appearance and histology. Eighty-eight percent of those treated with naltrexone had at least a 70-point decline in CDAI scores compared to 40% of placebo-treated patients (p = 0.009). After 12 weeks, 78% of subjects treated with naltrexone exhibited an endoscopic response as indicated by a 5-point decline in the Crohn's disease endoscopy index severity score (CDEIS) from baseline compared to 28% response in placebo-treated controls (p = 0.008), and 33% achieved remission with a CDEIS score <6, whereas only 8% of those on placebo showed the same change. Fatigue was the only side effect reported that was significantly greater in subjects receiving placebo.
Forty-two IBS patients participated in an open-label study. Participants received 0.5 mg PTI-901/day for 4 weeks and were evaluated during baseline, during treatment, and at 4-week follow-up. Patients recorded degree of abdominal pain, stool urgency, consistency, and frequency. Primary outcomes were number of pain-free days and overall symptom relief, evaluated by a global assessment score. Data were analyzed per protocol. Global assessment improved in 76% of 42 patients. During treatment, the mean weekly number of pain-free days increased from 0.5+/-1 to 1.25+/-2.14 (P=0.011). There were no significant adverse reactions. PTI-901 improves pain and overall feeling, and is well tolerated by IBS patients.
Diabetic neuropathy
63-year-old male, diagnosed with diabetic neuropathy for the last six years was prescribed one or two tablets every four to six hours as needed for pain. Patient takes between 4 to 8 tablets a day.
Started 4.5 mg of IMMEDIATE RELEASE
NALTREXONE in March of 2015 and within 3 days was able to cut down the number
of pills in half within 8 weeks patient stopped all pain medication, additional benefits included resolutions of RLS
Fibromyalgia ď&#x201A;ˇ
Thirty-one women with fibromyalgia participated in the randomized, double blind, placebo-controlled, and counterbalanced, crossover study. During the active drug phase, participants received 4.5 mg of oral naltrexone daily. An intensive longitudinal design was used to measure daily levels of pain. When contrasting the condition end points, we observed a significantly greater reduction of baseline pain in those taking low-dose naltrexone than in those taking placebo (28.8% reduction versus 18.0% reduction; P = 0.016). Low-dose naltrexone was also associated with improved general satisfaction with life (P = 0.045) and with improved mood (P = 0.039), but not improved fatigue or sleep. Thirty-two percent of participants met the criteria for response (defined as a significant reduction in pain plus a significant reduction in either fatigue or sleep problems) during low-dose naltrexone therapy, as contrasted with an 11% response rate during placebo therapy (P = 0.05). Lowdose naltrexone was rated equally tolerable as placebo, and no serious side effects were reported.
ď&#x201A;ˇ
Ten women meeting criteria for fibromyalgia and not taking an opioid medication. Were doses with immediate release Naltrexone, in addition to antagonizing opioid receptors on neurons, also inhibits microglia activity in the central nervous system. At doses (4.5 mg), immediate release naltrexone may inhibit the activity of microglia and reverse central and peripheral inflammation.
The results showed that
immediate release naltrexone at 4.5mg reduced fibromyalgia symptoms in the entire cohort, with a greater than 30% reduction of symptoms over placebo. In addition, laboratory visits showed that mechanical and heat pain thresholds were improved by the drug. Side effects (including insomnia and vivid dreams) were rare, and described as minor and transient. Baseline erythrocyte sedimentation rate predicted over 80% of the variance in drug response. Individuals with higher sedimentation rates (indicating general inflammatory processes) had the greatest reduction of symptoms in response to immediate release low-dose naltrexone. Which confirms the ability of immediate release naltrexone to decree pain and inflammation. Hashimoto's thyroiditis.
45-year-old woman diagnosed with Hashimoto’s 3/10/2019 Low energy, nerve pain, development of metabolic syndrome (insulin resistance), folliculitis that had not healed after 4 months, even after 28 days on an oral antibiotic, reduction in T3 hormone levels (which caused me to switch from synthroid to Nature Throid in order to optimize levels of T4 and T3 hormones). Started IMMEDIATE RELEASE NALTREXONE 1.5mg January of 2015.
Prior to starting IMMEDIATE RELEASE
NALTREXONE I was taking Advair, Nasacort, Albuterol, in addition to thyroid hormone, zyrtec, omeprazole, atorvastatin, metformin, and several supplements. After starting IMMEDIATE RELEASE NALTREXONE, I was able to go off the Advair, Nasacort, and Albuterol. Patients stated sleep quality has improved, energy levels have increased, and allergy symptoms have dramatically decreased, and has not suffered from asthma attacks since starting. No longer has pins-and-needles pain in her feet anymore, and the folliculitis finally healed after taking IMMEDIATE RELEASE NALTREXONE for a few weeks. Latest lab work was normal in all areas.
40 year old man was diagnosed October 2011with Hashimoto Thyroiditis, but believes that his auto-immune disease has progressed and stated over the last 2 years has battled Insomnia, extreme fatigue, bed bound for months at a time, anger, severe depression, brain fog, irritability and neck & back-muscle pain, and no longer responded to synthetic hormone like L-Thyroxin and Euthyrox. Started 1.5mg of IMMEDIATE RELEASE NALTREXONE for 2 months then 3mg and continues on 3mg in morning and 1mg at night side effect strange dreams. It took weeks to get my energy back and for the depression to go away. Patient was taking L-thyroxine and pain medications and 75mg Zoloft. Patients is off all medication accept IMMEDIATE RELEASE NALTREXONE and back at work.
50 year old woman diagnosed with hyopthyroid since 1992, and diagnosed July 2013 Hashimoto's, MTHFR, adrenal fatigue, estrogen dominance, low B12, low D Patients started at 1.5mg for 2 weeks then 3 mg for 4 weeks and 4.5mg and continues on IMMEDIATE RELEASE NALTREXONE today.
Patients was taking
Synthroid 150mcg, Compounded T3 25mcg, Progesterone 150mg, Plus lots of supplements like Magnesium, D3, Methyl B12, Methyl folate, Selenium, E, Amino Restore, CLA, NAC, DE, Adaptacin. Patients states she has regained energy, stamina, and am gaining my strength back, chronic 13 yr hip pain in very minimal, ear discharge stopped and gums do not bleed, Neck pain is gone, has stopped pain pills, TgAb lowered from 77 to <1, TPO lowered from 229 to 203. Patient continues on 4.5mg IMMEDIATE RELEASE NALTREXONE has stopped T3, decreased Synthroid from 150 to 50 and B12 went from 300 to 1785 after starting IMMEDIATE RELEASE NALTREXONE and IMMEDIATE RELEASE NALTREXONE helped my absorption issues and conversion of T4 to T3.
39-year-old woman diagnosed with Hashimoto’s her TPO levels were 350 when initiated T3/T4/19mcg capsules and immediate release IMMEDIATE RELEASE NALTREXONE 4.5mg in August 2011. Patients TPO levels returned to normal and patient reduced T3 to 2.25mg and continues on 4.5mg of IMMEDIATE RELEASE NALTREXONE
Shingles, or herpes zoster,
45-year-old woman diagnosed with Shingles in 2010 over 18 months had 8 major outbreaks, and was treated with acyclovir, and valacyclovir, as the outbreaks continued they prescribed Lidocaine patches and pain medications. In o help reduce the pain and the duration of shingles. Started 4.5mg of IMMEDIATE RELEASE NALTREXONE nightly in 2013 and have not had a single outbreak, additional benefit have not even gotten a cold
Inflammatory bowel disease.
16 year old boy diagnosed with Ulcerative Colitis in 2007 patient when first seen had lost 30 lb. and anemic, and surgery was being recommended, school attendance was sporadic. Patients was prescribed Remicade and GI specialists wanted to increase the dose and frequency of treatments. In May of 2007 patient started a high corroborate diet protocol and 4.5mg of IMMEDIATE RELEASE NALTREXONE at bedtime over the next five months patient gained 4.5mg IMMEDIATE RELEASE NALTREXONE, returned to school with attendance 100 percent, first time since in two years he was able to run track and cross-country without missing an event. Patient continues on diet protocol plus 4.5mg of IMMEDIATE RELEASE NALTREXONE
Myasthenia gravis. •68 year old woman has suffered with myasthenia gravis for over 20 years with effect on her eyesight, chewing, swallowing and. Weakness and numbness of both legs and arms. Patient started IMMEDIATE RELEASE NALTREXONE at 4.5mg per day at bedtime. Over the next 3 weeks her eyesight began to improve as well as the here other symptoms and her doctors said she was symptom free first time in over 20 years. Patient traveled out of the US and ran our of her IMMEDIATE RELEASE NALTREXONE and her symptoms began to return within 72 hours the worst was the double vision and muscle weakness. When she returned to the United States she immediately resumed her immediate release naltrexone treatment and has had no attacks since.
Multiple Sclerosis. A PILOT TRIAL OF LOW-DOSE NALTREXONE IN PRIMARY PROGRESSIVE MULTIPLE SCLEROSIS A sixth month phase II multicenter-pilot trial with a low dose of the opiate antagonist Naltrexone (LDN) has been carried out in 40 patients with primary progressive multiple sclerosis (PPMS). The primary end points were safety and tolerability. Secondary outcomes were efficacy on spasticity, pain, fatigue, depression, and quality of life. Clinical and biochemical evaluations were serially performed. Protein concentration of betaendorphins (BE) and mRNA levels and allelic variants of the mu-opioid receptor gene (OPRM1) were analyzed. Results Five dropouts and two major adverse events occurred. The remaining adverse events did not interfere with daily living. Neurological disability progressed in only one patient. A significant reduction of spasticity was measured at the end of the trial. BE concentration increased during the trial, but no association was found between OPRM1 variants and improvement of spasticity. Our data clearly indicate that LDN is safe and well tolerated in patients with PPMS. PILOT TRIAL ON LOW-DOSE NALTREXONE AND QUALITY OF LIFE IN MULTIPLE SCLEROSES WITH 80 PATIENTS: To evaluate the efficacy of 4.5mg nightly naltrexone on the quality of life of multiple sclerosis (MS) patients. This single-center, double-masked, placebo-controlled, crossover study evaluated the efficacy of 8 weeks of treatment with 4.5mg nightly naltrexone (low-dose naltrexone, LDN) on self-reported quality of life of MS patients. RESULTS: Eighty subjects with clinically definite MS were enrolled, and 60 subjects completed the trial. Ten withdrew before completing the first trial period: 8 for personal reasons, 1 for a non-MS-related adverse event, and 1 for perceived benefit. Database management errors occurred in 4 other subjects, and quality of life surveys were incomplete in 6 subjects for unknown reasons. The high rate of subject dropout and data management errors substantially reduced the trial's statistical power. LDN was well tolerated, and serious adverse events did not occur. LDN was associated with significant improvement on the following mental health quality of life measures: a 3.3-point improvement on the Mental Component Summary score of the Short Form-36 General Health Survey (p = 0.04), a 6-point improvement on the Mental Health Inventory (p < 0.01), a 1.6-point improvement on the Pain Effects Scale (p =. 04), and a 2.4-point improvement on the Perceived Deficits Questionnaire (p = 0.05). LDN significantly improved mental health quality of life indices. Further studies with LDN in MS are warranted. Retrospective Chart Review of MS Patients Receiving Low Dose Naltrexone (LDN) to Assess Safety, Tolerability, and Effect on Fatigue This study investigated the safety, tolerability, and benefits (fatigue, reduction) of LDN in patients with MS. It reviewed the number of patients who stopped taking LDN and if there were specific reasons for stopping the LDN. The frequency and variety of side effects that were specific to LDN use are reported.; A retrospective review was performed on 435 charts of MS patients who were seen in the Penn State Hershey out- patient Multiple Sclerosis Clinic between 1/1/2005 and 5/31/2012. There were 215 MS patients having exposure to LDN during the time of this study. RESULTS: The study confirmed an improvement in quality of life with the use of LDN over a long period of time. In addition to the assessment we review Brain MRIs and Spinal Cord MRIs that were obtained as part of the clinical status of the patient and standard of care.
â&#x20AC;˘42-year-old woman with M.S. of four years was started on 1.5mg of immediate release IMMEDIATE RELEASE NALTREXONE for two weeks then increased to 3mg for two weeks and has been on IMMEDIATE RELEASE NALTREXONE at 4.5mg for seven months. Her M.S. is of the fast deteriorating type with increasing weakness, spasticity and incoordination of her arms and legs with some cognitive ability deterioration apparent to her physicians-on each two months follow-up visit. Over a number the last six months since starting the IMMEDIATE RELEASE NALTREXONE, the disease has stabilized and the progressive deterioration has stopped. ď&#x201A;ˇ
70-year-old woman one with M.S. of 35 years was started on 3mg of immediate release IMMEDIATE RELEASE NALTREXONE for 30 days then increased to 4.5mg and has taken IMMEDIATE RELEASE NALTREXONE for two years. Her M.S. has been of
the slow deteriorating type with increasing weakness, spasticity and incoordination of her arms and legs with both deterioration of both eyesight and connectivity ability and deterioration apparent to her physicians on each six-month followup visit. Patient was homebound and wheelchair bound at the time she started immediate release IMMEDIATE RELEASE NALTREXONE at bedtime. Over the next three months she regained her ability to see and walk and her cognitive ability improved as well, the disease has stabilized and the progressive deterioration has stopped.
54-year-old man with MS of 8 years was started on 4.5mg of immediate release IMMEDIATE RELEASE NALTREXONE. Patients was diagnosed with was relapsing remitting M.S. in 2008 has been of the slow deteriorating type with increasing weakness, spasticity and incoordination of his arms and legs with both deterioration apparent to his physician on each six month follow up. Patient has been treated with Tysabri and Copaxone and they were getting ready to change his medicine once again as it was no longer effective so patient decided to begin treatment with immediate release IMMEDIATE RELEASE NALTREXONE. Over the last two and a half years since starting the IMMEDIATE RELEASE NALTREXONE, the disease has stabilized and the progressive deterioration has stopped and his last MRI showed brain lesion healing.
49 year old woman diagnosed with Relapsing Remitting MS in June 1999, prescribed a number of medications from Jan 1999 through September 20012 which included Avonex, Copaxone, Beta-Seron, Prednisone, 11mg Baclofen twice a day from 19992001. In September of 2002 was prescribed Topamax 100mg after patients suffered from 3 seizures. Patient was prescribed 4.5 immediate release IMMEDIATE RELEASE NALTREXONE with Topamax and patient continue both Topamax until 2006 at which time patients discontinued the use of Topamax and continues with 4.5mg of IMMEDIATE RELEASE NALTREXONE taken at bedtime with Vitamin D one a day and Firs oil. When patient started IMMEDIATE RELEASE NALTREXONE in 2002 over the next few months few spams, increasing body strength, less numbness and tingling, fewer headaches. Patient has not had a one relapse since starting IMMEDIATE RELEASE NALTREXONE and MRI over the last 8 years showed no progression of the disease and continues of 4.5mg immediate release IMMEDIATE RELEASE NALTREXONE.
33 year old woman diagnosed in 2001 Relapsing Remitting MS, and started on Avonex from 2002- mid 2003 with no major relapse. By Mid 2003 relapses were more frequent and started on Reib January of 2004 patients was laid off from her job due to MS symptoms that included poor balance, bladder problems, deteriorating vision and handwriting. Patient became wheelchair bound in March of
2004 due to leg weakness. Patients original doctor refused to prescribe IMMEDIATE RELEASE NALTREXONE. Patient in July 2004 was prescribed IMMEDIATE RELEASE NALTREXONE 3mg nightly within 3 days spams subsided and bladder urgency was reduced but all of my other MS related symptoms were improving. Patient was walking again with a cane for assistance within 10days of starting IMMEDIATE RELEASE NALTREXONE. In August of 2004 IMMEDIATE RELEASE NALTREXONE was increased to 4.5mg nightly with minimal side effects some insomnia the 30 days but then subsided. Patient last update was 2010 and was still driving, living alone and have some balance issues no relapses continue to take 4.5mg nightly.
55-year-old male was diagnosed with Relapsing Remitting MS in 1998, and Secondary Progressive in 2002. Patient’s chief symptoms extreme mixed sleep apnea, chronic obstructive pulmonary diseases (COPD) inability to walk, total deafness in left ear and inability to concentrate for any period of time. Patient prior to starting IMMEDIATE RELEASE NALTREXONE was from Feb 1998-Aug 2001 Avonex, 1999 to 2000 Copaxone and Avonex together; March 2002-June of 2005 Rebit and September 2001 to 2002 Cytoxan (chemotherapy) August 2001 plasma exchange for eleven days. From 2001-2005 multiple infusion of Solmefrol IV steroids (minimum of 4 times a year) Gabapentin 3 times a day, Clonazpam 1 time nightly, Effexor XR 2 times a day 37mg, Acicept 1 time a day 11mg, Flomax 1 time a day 11mg Baclofen 3 times a day 10 MEQ CAP, and Furosemide 1 time a day 40mg. As of June of 2005 was on oxygen 24/7, wheelchair bound, MS flairs one a month. Patient in July of 2005 was prescribed 1.5mg of IMMEDIATE RELEASE NALTREXONE one time a day at bedtime increasing to 3mg of IMMEDIATE RELEASE NALTREXONE within 7 days stopped taking Rebit, no real improvement in the first three months accept no flair of MS. Patient improved slowly over the next 3 months, was able to take time off oxygen to extended periods of time, strength returned in in legs and arms and was able to take short walks with walker, then longer walks then upgraded from wheelchair to cane. Sleep began to improve. At six month all my tests results improved. Patients continues to do well is driving and only taking 4.5mg IMMEDIATE RELEASE NALTREXONE and Vitamin D Supplements September 2012.
46 year old female, was diagnosed with relapsing remitting MS in 2002 and managed the symptoms on a combination of MS drugs until 2010 when she was forced to go part time due difficulty with brain fog, severe insomnia, severe fatigue and debilitating frequent exacerbations. Also poor sleep quality. Treatment Plan: January 2005 IMMEDIATE RELEASE NALTREXONE 1.5 mg increasing to 4.5mg nightly at bedtime. In addition to IMMEDIATE RELEASE NALTREXONE patient was prescribed bio-identical progesterone and estriol 8 mg, Cortef for adrenal support MS,
response, Patient began sleeping better within 2 week, Energy levels improved and brain fog, started to clear within a month, Exacerbations became less frequent and have stopped, patient returned to work within 12 months of starting the protocol patient has been back at work for 5 years without an exacerbation
54-year-old male diagnosed with secondary-progressive multiple sclerosis (SPMS) in 2006 current treatment included Tysabri infusions difficulty walking, severe heat sensitivity unable to work. In July of 2009 patient started immediate release IMMEDIATE RELEASE NALTREXONE at 1.5mg for one week to 3mg in week two patient saw immediate improvement increased stamina, was able to return to work, in January of 2011 MRI showed reduced plaque and lesion size
This study investigated the safety, tolerability, and benefits (fatigue, reduction) of IMMEDIATE RELEASE NALTREXONE (LDN) in patients with MS. It reviewed the number of patients who stopped taking IMMEDIATE RELEASE NALTREXONE (LDN) and if there were specific reasons for stopping the IMMEDIATE RELEASE NALTREXONE (LDN). The frequency and variety of side effects that were specific to IMMEDIATE RELEASE NALTREXONE (LDN) use are reported.
A retrospective review
was performed on 435 charts of MS patients who were seen in the Penn State Hershey out- patient Multiple Sclerosis Clinic between 1/1/2005 and 5/31/2012. There were 215 MS patients having exposure to IMMEDIATE RELEASE NALTREXONE (LDN) during the time of this study. RESULTS: The study confirmed an improvement in quality of life with the use of IMMEDIATE RELEASE NALTREXONE (LDN) over a long period of time. In addition to the assessment we review Brain MRIs and Spinal Cord MRIs that were obtained as part of the clinical status of the patient and standard of care. There were essentially no MRIs obtained immediately before IMMEDIATE RELEASE NALTREXONE (LDN) was started as would have been ideal in a prospective study.
The average number of days of the Brain MRI before treatment with IMMEDIATE RELEASE NALTREXONE (LDN) was started was 444 days with a maximum of 4751 days. The average number of days to the latest Brain MRI after IMMEDIATE RELEASE NALTREXONE (LDN) was started was 708 with a maximum of 1772 days of 215 patients on IMMEDIATE RELEASE NALTREXONE (LDN) 113 MRI scans showed stable, 14 showed improvement, 28 slightly worse. The Slightly Worse MRI series indicated that new but inactive lesion(s) were identified when compared to the pretreatment study MRI. On the quality of life surveys showed 83 patients said they had improved, 92 patients said they were stable and 9 worse. The remainder of the patients did not continue on IMMEDIATE RELEASE NALTREXONE (LDN).
Psoriatic arthritis
55 Year old man with psoriatic arthritis for 8 years and was being treated with Humira and was concerned about the side effects of the drug as he had been hospitalized four times over a 18 month period for Pneumonia and kidney infections and decided to begin treatment with IMMEDIATE RELEASE NALTREXONE. He started on 4.5mg of immediate release IMMEDIATE RELEASE NALTREXONE fat bedtime. Within 10 days of starting IMMEDIATE RELEASE NALTREXONE he was able to discontinue all paid medications as well as the Humira and over the last six months since starting the IMMEDIATE RELEASE NALTREXONE, the disease has stabilized and the progressive deterioration has stopped
Rheumatoid arthritis (RA)
40 year old woman diagnosed with Rheumatoid Arthritis in 2006 and was being treated with methotrexate and plaquenil but patients continued with pain and fatigue. In April of 2009 patients started treated with 1.5mg of immediate release IMMEDIATE RELEASE NALTREXONE and titrated up to 4.5mg over two months. Tried stopping methotrexate in July 2009 starting have bad flares and again started methotrexate Successfully discontinued methotrexate March of 2010 and then discontinued plaquenil in October of 2010 patient continues on 4.5mg of immediate release IMMEDIATE RELEASE NALTREXONE.
Systemic sclerosis (scleroderma).
44 year old male diagnosed with Systemic Lupus by Rheumatologist in in 2005 patient suffered from malar rash, Reynaud’s Disease & Arthritic Pain, difficulty with mobility multiple hospital admission since 2005 fluid on the lungs and skin blister: began treatment of 3mg of IMMEDIATE RELEASE NALTREXONE March 2013 increasing to 4.5mg in May of 2013. Patient within three weeks after beginning treatment with IMMEDIATE RELEASE NALTREXONE had improved mobility, within 4 months joints improved walking daily, skin cleared almost 100% blood results improving. Patient before starting IMMEDIATE RELEASE NALTREXONE was on Imuran 75mg, treated with high dose steroids, and ace inhibitor, ramipril.
Patients
continues on take 4.5mg of IMMEDIATE RELEASE NALTREXONE and has had no hospital stays since March of 2013
32 year old female diagnosed with systemic lupus with psoriasis, IBS and chronic fatigue develops joint pain, increasing abdominal pain and malar rash • Patient refused immunosuppressing drugs and tried supplements and healthy diet • Patient
contracted MRSA in 2010 in hospital • MRSA treated with oral drugs twice, then with IV drugs patient developed sepsis. Infection kept recurring boils. • Antibiotics work, but patient continued to get sicker and sicker with worsening symptoms and rising ANA although no organ damage. • Unable to take immunomodulating drugs due to MRSA recurrence and intolerant to others standard treatments for lupus, her doctors informed here that they could offer no help and she needed to put her affairs in order as it was only a matter or time. In 2012 office, she receives: HBO, acupuncture, supplement tailoring, treatment for mercury toxicity, food elimination diet then rotation, treatment for yeast overgrowth; • She is started on IMMEDIATE RELEASE NALTREXONE 1.5 mg, but is unable to take it due to insomnia and pruritis. • IMMEDIATE RELEASE NALTREXONE changed to liquid form and started at 0.5 mg, IMMEDIATE RELEASE NALTREXONE decreased to 0.1 mg and increased by 0.1 mg once a week until she reached 1.5 mg, which is where she stays. Lupus, in remission currently still on IMMEDIATE RELEASE NALTREXONE, supplements, healthy diet and lifestyle No recurrence of MRSA in 8 years No signs or symptoms of lupus and normal ANA for 7 years Intestinal symptoms resolved for 2 years with some issues when patient does not stay on a healthy diet. Psoriasis mostly resolved
Fibromyalgia
Twenty-five patients diagnosed with fibromyalgia treatment with (immediate release naltrexone) LDN open label study carried out at a single center Of the 22 patients completing the study, using 4.5mg immediate release naltrexone 7 (32%) remained on naltrexone monotherapy throughout the study. At Month 3, a 19.5% overall improvement in FIQR was “The patients reported decreases in anxiety, pain, and sleeping habits from baseline reported. Eleven patients (50%) had an average of a 41% improvement in FIQR.
Double Blind Crossover to determine whether low dosages (4.5 mg/day) of immediate release naltrexone reduce fibromyalgia severity as compared with the nonspecific effects of placebo. When contrasting the condition end points, we observed a significantly greater reduction of baseline pain in those taking low-dose naltrexone than in those taking placebo (28.8% reduction versus 18.0% reduction; P = 0.016). Low-dose naltrexone was also associated with improved general satisfaction with life (P = 0.045) and with improved mood (P = 0.039), but not improved fatigue or sleep. Thirty-two percent of participants met the criteria for
response (defined as a significant reduction in pain plus a significant reduction in either fatigue or sleep problems) during low-dose naltrexone therapy, as contrasted with an 11% response rate during placebo therapy (P = 0.05). Low-dose naltrexone was rated equally tolerable as placebo, and no serious side effects were reported.
Woman age 53 diagnosed 1998 Fibromyalgia and Epstein Barr, had to quit work, in pain and very depressed. Various treatments over the years for pain prescribed and other problems with the disease.
Was prescribed IMMEDIATE RELEASE
NALTREXONE .5mg in 2004 and saw improvement by the following day slight, continued to see improvement and increased to 3mg of the next 60 days, has more energy and the pain level has decreased by 90% and cognitive ability and mood is better and no longer need to take anti-depressants. Rheumatoid arthritis
59 year old male diagnosed 5 years ago with RA was being treated with Methotrexate 25 mg per week and Remicade 300 U every 6 weeks, the fatigue and pain continued, along with the inflammation and general weakness. Sleep disturbed nightly due to pain in my shoulders and hips. Patient felt her life was not acceptable and none of the immunosuppression drugs were helping. In 2007 patient started 4.5mg of immediate release naltrexone at bedtime and within 7 days patient stooped all traditional RA medications. Within two weeks patients stopped even ibuprophen. Rheumatoid factor has gone from 127 to 66 in 4 months and has stayed stable. Fatigue is gone. Occasionally patient has pain but it is easily controlled with a normal dosage of ibuprophen.
63-year-old female, diagnosed with RA in 1999 stayed very active until 2005 on a combination of Methotrexate and Prednisone but was have difficulty maintaining her business due to fatigue and severe joint pain with deformity of her hands and elbows.
Patient was told to increase her does and start a second
immunomodulating drug.
Patient no longer wanted to continue with
immunosuppression drug or steroids due to the side effects. In 2008 patient started a new protocol which included dietary changes, supplements, acupuncture, microcurrent therapy, toxicity testing and treatment, Bio-identical hormones, adrenal support and thyroid started, immediate release naltrexone started at 4.5 mg RA, discontinued the use of all other RA medication over a three week period. 7 years later, still not on any other drugs, RA has not advanced; she has no pain that can’t be handled with aspirin.
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